fluid-contracts-public/deployments/mainnet/dump/0x8B062a14012dc9968D96d3AeA5249243aDaC3b03.json

{
  "address": "0x8B062a14012dc9968D96d3AeA5249243aDaC3b03",
  "abi": [
    {
      "inputs": [
        {
          "internalType": "address",
          "name": "liquidity_",
          "type": "address"
        },
        {
          "internalType": "address",
          "name": "vaultAdminImplementation_",
          "type": "address"
        },
        {
          "internalType": "address",
          "name": "vaultSecondaryImplementation_",
          "type": "address"
        }
      ],
      "stateMutability": "nonpayable",
      "type": "constructor"
    },
    {
      "inputs": [
        {
          "internalType": "uint256",
          "name": "colLiquidated",
          "type": "uint256"
        },
        {
          "internalType": "uint256",
          "name": "debtLiquidated",
          "type": "uint256"
        }
      ],
      "name": "FluidLiquidateResult",
      "type": "error"
    },
    {
      "inputs": [
        {
          "internalType": "uint256",
          "name": "errorId_",
          "type": "uint256"
        }
      ],
      "name": "FluidVaultError",
      "type": "error"
    },
    {
      "anonymous": false,
      "inputs": [
        {
          "indexed": true,
          "internalType": "address",
          "name": "vault",
          "type": "address"
        },
        {
          "indexed": false,
          "internalType": "uint256",
          "name": "vaultId",
          "type": "uint256"
        },
        {
          "indexed": true,
          "internalType": "address",
          "name": "supplyToken",
          "type": "address"
        },
        {
          "indexed": true,
          "internalType": "address",
          "name": "borrowToken",
          "type": "address"
        }
      ],
      "name": "VaultT1Deployed",
      "type": "event"
    },
    {
      "inputs": [],
      "name": "ADDRESS_THIS",
      "outputs": [
        {
          "internalType": "address",
          "name": "",
          "type": "address"
        }
      ],
      "stateMutability": "view",
      "type": "function"
    },
    {
      "inputs": [],
      "name": "ADMIN_IMPLEMENTATION",
      "outputs": [
        {
          "internalType": "address",
          "name": "",
          "type": "address"
        }
      ],
      "stateMutability": "view",
      "type": "function"
    },
    {
      "inputs": [],
      "name": "LIQUIDITY",
      "outputs": [
        {
          "internalType": "address",
          "name": "",
          "type": "address"
        }
      ],
      "stateMutability": "view",
      "type": "function"
    },
    {
      "inputs": [],
      "name": "SECONDARY_IMPLEMENTATION",
      "outputs": [
        {
          "internalType": "address",
          "name": "",
          "type": "address"
        }
      ],
      "stateMutability": "view",
      "type": "function"
    },
    {
      "inputs": [],
      "name": "VAULT_T1_CREATIONCODE_ADDRESS",
      "outputs": [
        {
          "internalType": "address",
          "name": "",
          "type": "address"
        }
      ],
      "stateMutability": "view",
      "type": "function"
    },
    {
      "inputs": [
        {
          "internalType": "address",
          "name": "supplyToken_",
          "type": "address"
        },
        {
          "internalType": "address",
          "name": "borrowToken_",
          "type": "address"
        }
      ],
      "name": "vaultT1",
      "outputs": [
        {
          "internalType": "bytes",
          "name": "vaultCreationBytecode_",
          "type": "bytes"
        }
      ],
      "stateMutability": "nonpayable",
      "type": "function"
    }
  ],
  "transactionHash": "0x9baa82e80d2a41bf22c31e259573976170687a945188762230e552c25153a789",
  "receipt": {
    "to": "0x4e59b44847b379578588920cA78FbF26c0B4956C",
    "from": "0x0Ed35B1609Ec45c7079E80d11149a52717e4859A",
    "contractAddress": null,
    "transactionIndex": 82,
    "gasUsed": "6148370",
    "logsBloom": "0x00000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000",
    "blockHash": "0xebc7883071f816c8a9543fb36b3b17637202847ebff57a8bc1caabe21f9e3f5e",
    "transactionHash": "0x9baa82e80d2a41bf22c31e259573976170687a945188762230e552c25153a789",
    "logs": [],
    "blockNumber": 19250375,
    "cumulativeGasUsed": "13713196",
    "status": 1,
    "byzantium": true
  },
  "args": [
    "0x52Aa899454998Be5b000Ad077a46Bbe360F4e497",
    "0x8730d7a5aF435678b2686289eEB6A74A042081e6",
    "0x7726A2Da967c695531CEe326d081B72ec0F115DD"
  ],
  "numDeployments": 4,
  "solcInputHash": "c529dca7134770258a364a62696f0a8c",
  "metadata": "{\"compiler\":{\"version\":\"0.8.21+commit.d9974bed\"},\"language\":\"Solidity\",\"output\":{\"abi\":[{\"inputs\":[{\"internalType\":\"address\",\"name\":\"liquidity_\",\"type\":\"address\"},{\"internalType\":\"address\",\"name\":\"vaultAdminImplementation_\",\"type\":\"address\"},{\"internalType\":\"address\",\"name\":\"vaultSecondaryImplementation_\",\"type\":\"address\"}],\"stateMutability\":\"nonpayable\",\"type\":\"constructor\"},{\"inputs\":[{\"internalType\":\"uint256\",\"name\":\"colLiquidated\",\"type\":\"uint256\"},{\"internalType\":\"uint256\",\"name\":\"debtLiquidated\",\"type\":\"uint256\"}],\"name\":\"FluidLiquidateResult\",\"type\":\"error\"},{\"inputs\":[{\"internalType\":\"uint256\",\"name\":\"errorId_\",\"type\":\"uint256\"}],\"name\":\"FluidVaultError\",\"type\":\"error\"},{\"anonymous\":false,\"inputs\":[{\"indexed\":true,\"internalType\":\"address\",\"name\":\"vault\",\"type\":\"address\"},{\"indexed\":false,\"internalType\":\"uint256\",\"name\":\"vaultId\",\"type\":\"uint256\"},{\"indexed\":true,\"internalType\":\"address\",\"name\":\"supplyToken\",\"type\":\"address\"},{\"indexed\":true,\"internalType\":\"address\",\"name\":\"borrowToken\",\"type\":\"address\"}],\"name\":\"VaultT1Deployed\",\"type\":\"event\"},{\"inputs\":[],\"name\":\"ADDRESS_THIS\",\"outputs\":[{\"internalType\":\"address\",\"name\":\"\",\"type\":\"address\"}],\"stateMutability\":\"view\",\"type\":\"function\"},{\"inputs\":[],\"name\":\"ADMIN_IMPLEMENTATION\",\"outputs\":[{\"internalType\":\"address\",\"name\":\"\",\"type\":\"address\"}],\"stateMutability\":\"view\",\"type\":\"function\"},{\"inputs\":[],\"name\":\"LIQUIDITY\",\"outputs\":[{\"internalType\":\"address\",\"name\":\"\",\"type\":\"address\"}],\"stateMutability\":\"view\",\"type\":\"function\"},{\"inputs\":[],\"name\":\"SECONDARY_IMPLEMENTATION\",\"outputs\":[{\"internalType\":\"address\",\"name\":\"\",\"type\":\"address\"}],\"stateMutability\":\"view\",\"type\":\"function\"},{\"inputs\":[],\"name\":\"VAULT_T1_CREATIONCODE_ADDRESS\",\"outputs\":[{\"internalType\":\"address\",\"name\":\"\",\"type\":\"address\"}],\"stateMutability\":\"view\",\"type\":\"function\"},{\"inputs\":[{\"internalType\":\"address\",\"name\":\"supplyToken_\",\"type\":\"address\"},{\"internalType\":\"address\",\"name\":\"borrowToken_\",\"type\":\"address\"}],\"name\":\"vaultT1\",\"outputs\":[{\"internalType\":\"bytes\",\"name\":\"vaultCreationBytecode_\",\"type\":\"bytes\"}],\"stateMutability\":\"nonpayable\",\"type\":\"function\"}],\"devdoc\":{\"events\":{\"VaultT1Deployed(address,uint256,address,address)\":{\"params\":{\"borrowToken\":\"The address of the borrow token.\",\"supplyToken\":\"The address of the supply token.\",\"vault\":\"The address of the newly deployed vault.\",\"vaultId\":\"The id of the newly deployed vault.\"}}},\"kind\":\"dev\",\"methods\":{\"vaultT1(address,address)\":{\"params\":{\"borrowToken_\":\"The address of the borrow token.\",\"supplyToken_\":\"The address of the supply token.\"},\"returns\":{\"vaultCreationBytecode_\":\" Returns the bytecode of the new vault to deploy.\"}}},\"version\":1},\"userdoc\":{\"errors\":{\"FluidLiquidateResult(uint256,uint256)\":[{\"notice\":\"used to simulate liquidation to find the maximum liquidatable amounts\"}]},\"events\":{\"VaultT1Deployed(address,uint256,address,address)\":{\"notice\":\"Emitted when a new vaultT1 is deployed.\"}},\"kind\":\"user\",\"methods\":{\"ADDRESS_THIS()\":{\"notice\":\"address of this contract\"},\"ADMIN_IMPLEMENTATION()\":{\"notice\":\"address of Admin implementation\"},\"LIQUIDITY()\":{\"notice\":\"address of liquidity contract\"},\"SECONDARY_IMPLEMENTATION()\":{\"notice\":\"address of Secondary implementation\"},\"VAULT_T1_CREATIONCODE_ADDRESS()\":{\"notice\":\"SSTORE2 pointer for the VaultT1 creation code. Stored externally to reduce factory bytecode\"},\"vaultT1(address,address)\":{\"notice\":\"Computes vaultT1 bytecode for the given supply token (`supplyToken_`) and borrow token (`borrowToken_`).                                 This will be called by the VaultFactory via .delegateCall\"}},\"version\":1}},\"settings\":{\"compilationTarget\":{\"contracts/protocols/vault/factory/deploymentLogics/vaultT1Logic.sol\":\"FluidVaultT1DeploymentLogic\"},\"evmVersion\":\"paris\",\"libraries\":{},\"metadata\":{\"bytecodeHash\":\"ipfs\",\"useLiteralContent\":true},\"optimizer\":{\"enabled\":true,\"runs\":10000000},\"remappings\":[]},\"sources\":{\"@openzeppelin/contracts/token/ERC721/IERC721.sol\":{\"content\":\"// SPDX-License-Identifier: MIT\\n// OpenZeppelin Contracts (last updated v4.8.0) (token/ERC721/IERC721.sol)\\n\\npragma solidity ^0.8.0;\\n\\nimport \\\"../../utils/introspection/IERC165.sol\\\";\\n\\n/**\\n * @dev Required interface of an ERC721 compliant contract.\\n */\\ninterface IERC721 is IERC165 {\\n    /**\\n     * @dev Emitted when `tokenId` token is transferred from `from` to `to`.\\n     */\\n    event Transfer(address indexed from, address indexed to, uint256 indexed tokenId);\\n\\n    /**\\n     * @dev Emitted when `owner` enables `approved` to manage the `tokenId` token.\\n     */\\n    event Approval(address indexed owner, address indexed approved, uint256 indexed tokenId);\\n\\n    /**\\n     * @dev Emitted when `owner` enables or disables (`approved`) `operator` to manage all of its assets.\\n     */\\n    event ApprovalForAll(address indexed owner, address indexed operator, bool approved);\\n\\n    /**\\n     * @dev Returns the number of tokens in ``owner``'s account.\\n     */\\n    function balanceOf(address owner) external view returns (uint256 balance);\\n\\n    /**\\n     * @dev Returns the owner of the `tokenId` token.\\n     *\\n     * Requirements:\\n     *\\n     * - `tokenId` must exist.\\n     */\\n    function ownerOf(uint256 tokenId) external view returns (address owner);\\n\\n    /**\\n     * @dev Safely transfers `tokenId` token from `from` to `to`.\\n     *\\n     * Requirements:\\n     *\\n     * - `from` cannot be the zero address.\\n     * - `to` cannot be the zero address.\\n     * - `tokenId` token must exist and be owned by `from`.\\n     * - If the caller is not `from`, it must be approved to move this token by either {approve} or {setApprovalForAll}.\\n     * - If `to` refers to a smart contract, it must implement {IERC721Receiver-onERC721Received}, which is called upon a safe transfer.\\n     *\\n     * Emits a {Transfer} event.\\n     */\\n    function safeTransferFrom(\\n        address from,\\n        address to,\\n        uint256 tokenId,\\n        bytes calldata data\\n    ) external;\\n\\n    /**\\n     * @dev Safely transfers `tokenId` token from `from` to `to`, checking first that contract recipients\\n     * are aware of the ERC721 protocol to prevent tokens from being forever locked.\\n     *\\n     * Requirements:\\n     *\\n     * - `from` cannot be the zero address.\\n     * - `to` cannot be the zero address.\\n     * - `tokenId` token must exist and be owned by `from`.\\n     * - If the caller is not `from`, it must have been allowed to move this token by either {approve} or {setApprovalForAll}.\\n     * - If `to` refers to a smart contract, it must implement {IERC721Receiver-onERC721Received}, which is called upon a safe transfer.\\n     *\\n     * Emits a {Transfer} event.\\n     */\\n    function safeTransferFrom(\\n        address from,\\n        address to,\\n        uint256 tokenId\\n    ) external;\\n\\n    /**\\n     * @dev Transfers `tokenId` token from `from` to `to`.\\n     *\\n     * WARNING: Note that the caller is responsible to confirm that the recipient is capable of receiving ERC721\\n     * or else they may be permanently lost. Usage of {safeTransferFrom} prevents loss, though the caller must\\n     * understand this adds an external call which potentially creates a reentrancy vulnerability.\\n     *\\n     * Requirements:\\n     *\\n     * - `from` cannot be the zero address.\\n     * - `to` cannot be the zero address.\\n     * - `tokenId` token must be owned by `from`.\\n     * - If the caller is not `from`, it must be approved to move this token by either {approve} or {setApprovalForAll}.\\n     *\\n     * Emits a {Transfer} event.\\n     */\\n    function transferFrom(\\n        address from,\\n        address to,\\n        uint256 tokenId\\n    ) external;\\n\\n    /**\\n     * @dev Gives permission to `to` to transfer `tokenId` token to another account.\\n     * The approval is cleared when the token is transferred.\\n     *\\n     * Only a single account can be approved at a time, so approving the zero address clears previous approvals.\\n     *\\n     * Requirements:\\n     *\\n     * - The caller must own the token or be an approved operator.\\n     * - `tokenId` must exist.\\n     *\\n     * Emits an {Approval} event.\\n     */\\n    function approve(address to, uint256 tokenId) external;\\n\\n    /**\\n     * @dev Approve or remove `operator` as an operator for the caller.\\n     * Operators can call {transferFrom} or {safeTransferFrom} for any token owned by the caller.\\n     *\\n     * Requirements:\\n     *\\n     * - The `operator` cannot be the caller.\\n     *\\n     * Emits an {ApprovalForAll} event.\\n     */\\n    function setApprovalForAll(address operator, bool _approved) external;\\n\\n    /**\\n     * @dev Returns the account approved for `tokenId` token.\\n     *\\n     * Requirements:\\n     *\\n     * - `tokenId` must exist.\\n     */\\n    function getApproved(uint256 tokenId) external view returns (address operator);\\n\\n    /**\\n     * @dev Returns if the `operator` is allowed to manage all of the assets of `owner`.\\n     *\\n     * See {setApprovalForAll}\\n     */\\n    function isApprovedForAll(address owner, address operator) external view returns (bool);\\n}\\n\",\"keccak256\":\"0xab28a56179c1db258c9bf5235b382698cb650debecb51b23d12be9e241374b68\",\"license\":\"MIT\"},\"@openzeppelin/contracts/token/ERC721/extensions/IERC721Enumerable.sol\":{\"content\":\"// SPDX-License-Identifier: MIT\\n// OpenZeppelin Contracts (last updated v4.5.0) (token/ERC721/extensions/IERC721Enumerable.sol)\\n\\npragma solidity ^0.8.0;\\n\\nimport \\\"../IERC721.sol\\\";\\n\\n/**\\n * @title ERC-721 Non-Fungible Token Standard, optional enumeration extension\\n * @dev See https://eips.ethereum.org/EIPS/eip-721\\n */\\ninterface IERC721Enumerable is IERC721 {\\n    /**\\n     * @dev Returns the total amount of tokens stored by the contract.\\n     */\\n    function totalSupply() external view returns (uint256);\\n\\n    /**\\n     * @dev Returns a token ID owned by `owner` at a given `index` of its token list.\\n     * Use along with {balanceOf} to enumerate all of ``owner``'s tokens.\\n     */\\n    function tokenOfOwnerByIndex(address owner, uint256 index) external view returns (uint256);\\n\\n    /**\\n     * @dev Returns a token ID at a given `index` of all the tokens stored by the contract.\\n     * Use along with {totalSupply} to enumerate all tokens.\\n     */\\n    function tokenByIndex(uint256 index) external view returns (uint256);\\n}\\n\",\"keccak256\":\"0xd1556954440b31c97a142c6ba07d5cade45f96fafd52091d33a14ebe365aecbf\",\"license\":\"MIT\"},\"@openzeppelin/contracts/utils/introspection/IERC165.sol\":{\"content\":\"// SPDX-License-Identifier: MIT\\n// OpenZeppelin Contracts v4.4.1 (utils/introspection/IERC165.sol)\\n\\npragma solidity ^0.8.0;\\n\\n/**\\n * @dev Interface of the ERC165 standard, as defined in the\\n * https://eips.ethereum.org/EIPS/eip-165[EIP].\\n *\\n * Implementers can declare support of contract interfaces, which can then be\\n * queried by others ({ERC165Checker}).\\n *\\n * For an implementation, see {ERC165}.\\n */\\ninterface IERC165 {\\n    /**\\n     * @dev Returns true if this contract implements the interface defined by\\n     * `interfaceId`. See the corresponding\\n     * https://eips.ethereum.org/EIPS/eip-165#how-interfaces-are-identified[EIP section]\\n     * to learn more about how these ids are created.\\n     *\\n     * This function call must use less than 30 000 gas.\\n     */\\n    function supportsInterface(bytes4 interfaceId) external view returns (bool);\\n}\\n\",\"keccak256\":\"0x447a5f3ddc18419d41ff92b3773fb86471b1db25773e07f877f548918a185bf1\",\"license\":\"MIT\"},\"contracts/infiniteProxy/interfaces/iProxy.sol\":{\"content\":\"// SPDX-License-Identifier: MIT\\npragma solidity 0.8.21;\\n\\ninterface IProxy {\\n    function setAdmin(address newAdmin_) external;\\n\\n    function setDummyImplementation(address newDummyImplementation_) external;\\n\\n    function addImplementation(address implementation_, bytes4[] calldata sigs_) external;\\n\\n    function removeImplementation(address implementation_) external;\\n\\n    function getAdmin() external view returns (address);\\n\\n    function getDummyImplementation() external view returns (address);\\n\\n    function getImplementationSigs(address impl_) external view returns (bytes4[] memory);\\n\\n    function getSigsImplementation(bytes4 sig_) external view returns (address);\\n\\n    function readFromStorage(bytes32 slot_) external view returns (uint256 result_);\\n}\\n\",\"keccak256\":\"0xbb605491d4bac08e816248feecae7dd17cfc1877c88b2e555abece2970f5ea00\",\"license\":\"MIT\"},\"contracts/libraries/bigMathMinified.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\n/// @title library that represents a number in BigNumber(coefficient and exponent) format to store in smaller bits.\\n/// @notice the number is divided into two parts: a coefficient and an exponent. This comes at a cost of losing some precision\\n/// at the end of the number because the exponent simply fills it with zeroes. This precision is oftentimes negligible and can\\n/// result in significant gas cost reduction due to storage space reduction.\\n/// Also note, a valid big number is as follows: if the exponent is > 0, then coefficient last bits should be occupied to have max precision.\\n/// @dev roundUp is more like a increase 1, which happens everytime for the same number.\\n/// roundDown simply sets trailing digits after coefficientSize to zero (floor), only once for the same number.\\nlibrary BigMathMinified {\\n    /// @dev constants to use for `roundUp` input param to increase readability\\n    bool internal constant ROUND_DOWN = false;\\n    bool internal constant ROUND_UP = true;\\n\\n    /// @dev converts `normal` number to BigNumber with `exponent` and `coefficient` (or precision).\\n    /// e.g.:\\n    /// 5035703444687813576399599 (normal) = (coefficient[32bits], exponent[8bits])[40bits]\\n    /// 5035703444687813576399599 (decimal) => 10000101010010110100000011111011110010100110100000000011100101001101001101011101111 (binary)\\n    ///                                     => 10000101010010110100000011111011000000000000000000000000000000000000000000000000000\\n    ///                                                                        ^-------------------- 51(exponent) -------------- ^\\n    /// coefficient = 1000,0101,0100,1011,0100,0000,1111,1011               (2236301563)\\n    /// exponent =                                            0011,0011     (51)\\n    /// bigNumber =   1000,0101,0100,1011,0100,0000,1111,1011,0011,0011     (572493200179)\\n    ///\\n    /// @param normal number which needs to be converted into Big Number\\n    /// @param coefficientSize at max how many bits of precision there should be (64 = uint64 (64 bits precision))\\n    /// @param exponentSize at max how many bits of exponent there should be (8 = uint8 (8 bits exponent))\\n    /// @param roundUp signals if result should be rounded down or up\\n    /// @return bigNumber converted bigNumber (coefficient << exponent)\\n    function toBigNumber(\\n        uint256 normal,\\n        uint256 coefficientSize,\\n        uint256 exponentSize,\\n        bool roundUp\\n    ) internal pure returns (uint256 bigNumber) {\\n        assembly {\\n            let lastBit_\\n            let number_ := normal\\n            if gt(number_, 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF) {\\n                number_ := shr(0x80, number_)\\n                lastBit_ := 0x80\\n            }\\n            if gt(number_, 0xFFFFFFFFFFFFFFFF) {\\n                number_ := shr(0x40, number_)\\n                lastBit_ := add(lastBit_, 0x40)\\n            }\\n            if gt(number_, 0xFFFFFFFF) {\\n                number_ := shr(0x20, number_)\\n                lastBit_ := add(lastBit_, 0x20)\\n            }\\n            if gt(number_, 0xFFFF) {\\n                number_ := shr(0x10, number_)\\n                lastBit_ := add(lastBit_, 0x10)\\n            }\\n            if gt(number_, 0xFF) {\\n                number_ := shr(0x8, number_)\\n                lastBit_ := add(lastBit_, 0x8)\\n            }\\n            if gt(number_, 0xF) {\\n                number_ := shr(0x4, number_)\\n                lastBit_ := add(lastBit_, 0x4)\\n            }\\n            if gt(number_, 0x3) {\\n                number_ := shr(0x2, number_)\\n                lastBit_ := add(lastBit_, 0x2)\\n            }\\n            if gt(number_, 0x1) {\\n                lastBit_ := add(lastBit_, 1)\\n            }\\n            if gt(number_, 0) {\\n                lastBit_ := add(lastBit_, 1)\\n            }\\n            if lt(lastBit_, coefficientSize) {\\n                // for throw exception\\n                lastBit_ := coefficientSize\\n            }\\n            let exponent := sub(lastBit_, coefficientSize)\\n            let coefficient := shr(exponent, normal)\\n            if and(roundUp, gt(exponent, 0)) {\\n                // rounding up is only needed if exponent is > 0, as otherwise the coefficient fully holds the original number\\n                coefficient := add(coefficient, 1)\\n                if eq(shl(coefficientSize, 1), coefficient) {\\n                    // case were coefficient was e.g. 111, with adding 1 it became 1000 (in binary) and coefficientSize 3 bits\\n                    // final coefficient would exceed it's size. -> reduce coefficent to 100 and increase exponent by 1.\\n                    coefficient := shl(sub(coefficientSize, 1), 1)\\n                    exponent := add(exponent, 1)\\n                }\\n            }\\n            if iszero(lt(exponent, shl(exponentSize, 1))) {\\n                // if exponent is >= exponentSize, the normal number is too big to fit within\\n                // BigNumber with too small sizes for coefficient and exponent\\n                revert(0, 0)\\n            }\\n            bigNumber := shl(exponentSize, coefficient)\\n            bigNumber := add(bigNumber, exponent)\\n        }\\n    }\\n\\n    /// @dev get `normal` number from `bigNumber`, `exponentSize` and `exponentMask`\\n    function fromBigNumber(\\n        uint256 bigNumber,\\n        uint256 exponentSize,\\n        uint256 exponentMask\\n    ) internal pure returns (uint256 normal) {\\n        assembly {\\n            let coefficient := shr(exponentSize, bigNumber)\\n            let exponent := and(bigNumber, exponentMask)\\n            normal := shl(exponent, coefficient)\\n        }\\n    }\\n\\n    /// @dev gets the most significant bit `lastBit` of a `normal` number (length of given number of binary format).\\n    /// e.g.\\n    /// 5035703444687813576399599 = 10000101010010110100000011111011110010100110100000000011100101001101001101011101111\\n    /// lastBit =                   ^---------------------------------   83   ----------------------------------------^\\n    function mostSignificantBit(uint256 normal) internal pure returns (uint lastBit) {\\n        assembly {\\n            let number_ := normal\\n            if gt(normal, 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF) {\\n                number_ := shr(0x80, number_)\\n                lastBit := 0x80\\n            }\\n            if gt(number_, 0xFFFFFFFFFFFFFFFF) {\\n                number_ := shr(0x40, number_)\\n                lastBit := add(lastBit, 0x40)\\n            }\\n            if gt(number_, 0xFFFFFFFF) {\\n                number_ := shr(0x20, number_)\\n                lastBit := add(lastBit, 0x20)\\n            }\\n            if gt(number_, 0xFFFF) {\\n                number_ := shr(0x10, number_)\\n                lastBit := add(lastBit, 0x10)\\n            }\\n            if gt(number_, 0xFF) {\\n                number_ := shr(0x8, number_)\\n                lastBit := add(lastBit, 0x8)\\n            }\\n            if gt(number_, 0xF) {\\n                number_ := shr(0x4, number_)\\n                lastBit := add(lastBit, 0x4)\\n            }\\n            if gt(number_, 0x3) {\\n                number_ := shr(0x2, number_)\\n                lastBit := add(lastBit, 0x2)\\n            }\\n            if gt(number_, 0x1) {\\n                lastBit := add(lastBit, 1)\\n            }\\n            if gt(number_, 0) {\\n                lastBit := add(lastBit, 1)\\n            }\\n        }\\n    }\\n}\\n\",\"keccak256\":\"0xf0be1002909edf30aec3dc6623c2bd2407ed94064b62674c01032b844dec206a\",\"license\":\"BUSL-1.1\"},\"contracts/libraries/bigMathVault.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nimport { BigMathMinified } from \\\"./bigMathMinified.sol\\\";\\n\\n/// @title Extended version of BigMathMinified. Implements functions for normal operators (*, /, etc) modified to interact with big numbers.\\n/// @notice this is an optimized version mainly created by taking Fluid vault's codebase into consideration so it's use is limited for other cases.\\nlibrary BigMathVault {\\n    uint private constant COEFFICIENT_SIZE_DEBT_FACTOR = 35;\\n    uint private constant EXPONENT_SIZE_DEBT_FACTOR = 15;\\n    uint private constant COEFFICIENT_MAX_DEBT_FACTOR = (1 << COEFFICIENT_SIZE_DEBT_FACTOR) - 1;\\n    uint private constant EXPONENT_MAX_DEBT_FACTOR = (1 << EXPONENT_SIZE_DEBT_FACTOR) - 1;\\n    uint private constant DECIMALS_DEBT_FACTOR = 16384;\\n    uint internal constant MAX_MASK_DEBT_FACTOR = (1 << (COEFFICIENT_SIZE_DEBT_FACTOR + EXPONENT_SIZE_DEBT_FACTOR)) - 1;\\n\\n    // Having precision as 2**64 on vault\\n    uint internal constant PRECISION = 64;\\n    uint internal constant TWO_POWER_64 = 1 << PRECISION;\\n    // Max bit for 35 bits * 35 bits number will be 70\\n    // why do we use 69 then here instead of 70\\n    uint internal constant TWO_POWER_69_MINUS_1 = (1 << 69) - 1;\\n\\n    uint private constant COEFFICIENT_PLUS_PRECISION = COEFFICIENT_SIZE_DEBT_FACTOR + PRECISION; // 99\\n    uint private constant COEFFICIENT_PLUS_PRECISION_MINUS_1 = COEFFICIENT_PLUS_PRECISION - 1; // 98\\n    uint private constant TWO_POWER_COEFFICIENT_PLUS_PRECISION_MINUS_1 = (1 << COEFFICIENT_PLUS_PRECISION_MINUS_1) - 1; // (1 << 98) - 1;\\n    uint private constant TWO_POWER_COEFFICIENT_PLUS_PRECISION_MINUS_1_MINUS_1 =\\n        (1 << (COEFFICIENT_PLUS_PRECISION_MINUS_1 - 1)) - 1; // (1 << 97) - 1;\\n\\n    /// @dev multiplies a `normal` number with a `bigNumber1` and then divides by `bigNumber2`.\\n    /// @dev For vault's use case MUST always:\\n    ///      - bigNumbers have exponent size 15 bits\\n    ///      - bigNumbers have coefficient size 35 bits and have 35th bit always 1 (when exponent > 0 BigMath numbers have max precision)\\n    ///        so coefficients must always be in range 17179869184 <= coefficient <= 34359738367.\\n    ///      - bigNumber1 (debt factor) always have exponent >= 1 & <= 16384\\n    ///      - bigNumber2 (connection factor) always have exponent >= 1 & <= 32767 (15 bits)\\n    ///      - bigNumber2 always >= bigNumber1 (connection factor can never be < base branch debt factor)\\n    ///      - as a result of previous points, numbers must never be 0\\n    ///      - normal is positionRawDebt and is always within 10000 and type(int128).max\\n    /// @return normal * bigNumber1 / bigNumber2\\n    function mulDivNormal(uint256 normal, uint256 bigNumber1, uint256 bigNumber2) internal pure returns (uint256) {\\n        unchecked {\\n            // exponent2_ - exponent1_\\n            uint netExponent_ = (bigNumber2 & EXPONENT_MAX_DEBT_FACTOR) - (bigNumber1 & EXPONENT_MAX_DEBT_FACTOR);\\n            if (netExponent_ < 129) {\\n                // (normal * coefficient1_) / (coefficient2_ << netExponent_);\\n                return ((normal * (bigNumber1 >> EXPONENT_SIZE_DEBT_FACTOR)) /\\n                    ((bigNumber2 >> EXPONENT_SIZE_DEBT_FACTOR) << netExponent_));\\n            }\\n            // else:\\n            // biggest possible nominator: type(int128).max * 35bits max      =  5846006549323611672814739330865132078589370433536\\n            // smallest possible denominator: 17179869184 << 129 (= 1 << 163) = 11692013098647223345629478661730264157247460343808\\n            // -> can only ever be 0\\n            return 0;\\n        }\\n    }\\n\\n    /// @dev multiplies a `bigNumber` with normal `number1` and then divides by `TWO_POWER_64`.\\n    /// @dev For vault's use case (calculating new branch debt factor after liquidation):\\n    ///      - number1 is debtFactor, intialized as TWO_POWER_64 and reduced from there, hence it's always <= TWO_POWER_64 and always > 0.\\n    ///      - bigNumber is branch debt factor, which starts as ((X35 << 15) | (1 << 14)) and reduces from there.\\n    ///      - bigNumber must have have exponent size 15 bits and be >= 1 & <= 16384\\n    ///      - bigNumber must have coefficient size 35 bits and have 35th bit always 1 (when exponent > 0 BigMath numbers have max precision)\\n    ///        so coefficients must always be in range 17179869184 <= coefficient <= 34359738367.\\n    /// @param bigNumber Coefficient | Exponent.\\n    /// @param number1 normal number.\\n    /// @return result bigNumber * number1 / TWO_POWER_64.\\n    function mulDivBigNumber(uint256 bigNumber, uint256 number1) internal pure returns (uint256 result) {\\n        // using unchecked as we are only at 1 place in Vault and it won't overflow there.\\n        unchecked {\\n            uint256 _resultNumerator = (bigNumber >> EXPONENT_SIZE_DEBT_FACTOR) * number1; // bigNumber coefficient * normal number\\n            // 99% chances are that most sig bit should be 64 + 35 - 1 or 64 + 35 - 2\\n            // diff = mostSigBit. Can only ever be >= 35 and <= 98\\n            uint256 diff = (_resultNumerator > TWO_POWER_COEFFICIENT_PLUS_PRECISION_MINUS_1)\\n                ? COEFFICIENT_PLUS_PRECISION\\n                : (_resultNumerator > TWO_POWER_COEFFICIENT_PLUS_PRECISION_MINUS_1_MINUS_1)\\n                ? COEFFICIENT_PLUS_PRECISION_MINUS_1\\n                : BigMathMinified.mostSignificantBit(_resultNumerator);\\n\\n            // diff = difference in bits to make the _resultNumerator 35 bits again\\n            diff = diff - COEFFICIENT_SIZE_DEBT_FACTOR;\\n            _resultNumerator = _resultNumerator >> diff;\\n            // starting exponent is 16384, so exponent should never get 0 here\\n            result = (bigNumber & EXPONENT_MAX_DEBT_FACTOR) + diff;\\n            if (result > PRECISION) {\\n                result = (_resultNumerator << EXPONENT_SIZE_DEBT_FACTOR) + result - PRECISION; // divides by TWO_POWER_64 by reducing exponent by 64\\n            } else {\\n                // if number1 is small, e.g. 1e4 and bigNumber is also small e.g. coefficient = 17179869184 & exponent is at 50\\n                // then: resultNumerator = 171798691840000, diff most significant bit = 48, ending up with diff = 13\\n                // for exponent in result we end up doing: 50 + 13 - 64 -> underflowing exponent.\\n                // this should never happen anyway, but if it does better to revert than to continue with unknown effects.\\n                revert(); // debt factor should never become a BigNumber with exponent <= 0\\n            }\\n        }\\n    }\\n\\n    /// @dev multiplies a `bigNumber1` with another `bigNumber2`.\\n    /// @dev For vault's use case (calculating connection factor of merged branches userTickDebtFactor * connectionDebtFactor *... connectionDebtFactor):\\n    ///      - bigNumbers must have have exponent size 15 bits and be >= 1 & <= 32767\\n    ///      - bigNumber must have coefficient size 35 bits and have 35th bit always 1 (when exponent > 0 BigMath numbers have max precision)\\n    ///        so coefficients must always be in range 17179869184 <= coefficient <= 34359738367.\\n    /// @dev sum of exponents from `bigNumber1` `bigNumber2` should be > 16384.\\n    /// e.g. res = bigNumber1 * bigNumber2 = [(coe1, exp1) * (coe2, exp2)] >> decimal\\n    ///          = (coe1*coe2>>overflow, exp1+exp2+overflow-decimal)\\n    /// @param bigNumber1          BigNumber format with coefficient and exponent.\\n    /// @param bigNumber2          BigNumber format with coefficient and exponent.\\n    /// @return                    BigNumber format with coefficient and exponent\\n    function mulBigNumber(uint256 bigNumber1, uint256 bigNumber2) internal pure returns (uint256) {\\n        unchecked {\\n            // coefficient1_ * coefficient2_\\n            uint resCoefficient_ = (bigNumber1 >> EXPONENT_SIZE_DEBT_FACTOR) *\\n                (bigNumber2 >> EXPONENT_SIZE_DEBT_FACTOR);\\n            // res coefficient at min can be 17179869184 * 17179869184 =  295147905179352825856 (= 1 << 68; 69th bit as 1)\\n            // res coefficient at max can be 34359738367 * 34359738367 = 1180591620648691826689 (X35 * X35 fits in 70 bits)\\n            uint overflowLen_ = resCoefficient_ > TWO_POWER_69_MINUS_1\\n                ? COEFFICIENT_SIZE_DEBT_FACTOR\\n                : COEFFICIENT_SIZE_DEBT_FACTOR - 1;\\n            // overflowLen_ is either 34 or 35\\n            resCoefficient_ = resCoefficient_ >> overflowLen_;\\n\\n            // bigNumber2 is connection factor\\n            // exponent1_ + exponent2_ + overflowLen_ - decimals\\n            uint resExponent_ = ((bigNumber1 & EXPONENT_MAX_DEBT_FACTOR) +\\n                (bigNumber2 & EXPONENT_MAX_DEBT_FACTOR) +\\n                overflowLen_);\\n            if (resExponent_ < DECIMALS_DEBT_FACTOR) {\\n                // for this ever to happen, the debt factors used to calculate connection factors would have to be at extremely\\n                // unrealistic values. Like e.g.\\n                // branch3 (debt factor X35 << 15 | 16383) got merged into branch2 (debt factor X35 << 15 | 8190)\\n                // -> connection factor (divBigNumber): ((coe1<<precision_)/coe2>>overflowLen, exp1+decimal+overflowLen-exp2-precision_) so:\\n                // coefficient: (X35<<64)/X35 >> 30 = 17179869184\\n                // exponent: 8190+16384+30-16383-64 = 8157.\\n                // result: 17179869184 << 15 | 8157\\n                // and then branch2 into branch1 (debt factor X35 << 15 | 22). -> connection factor:\\n                // coefficient: (X35<<64)/X35 >> 30 = 17179869184\\n                // exponent: 22+16384+30-8190-64 = 8182.\\n                // result: 17179869184 << 15 | 8182\\n                // connection factors sum up (mulBigNumber): (coe1*coe2>>overflow, exp1+exp2+overflow-decimal)\\n                // exponent: 8182+8157+35-16384=16374-16384=-10. underflow.\\n                // this should never happen anyway, but if it does better to revert than to continue with unknown effects.\\n                revert();\\n            }\\n            resExponent_ = resExponent_ - DECIMALS_DEBT_FACTOR;\\n\\n            if (resExponent_ > EXPONENT_MAX_DEBT_FACTOR) {\\n                // if resExponent_ is not within limits that means user's got ~100% (something like 99.999999999999...)\\n                // this situation will probably never happen and this basically means user's position is ~100% liquidated\\n                return MAX_MASK_DEBT_FACTOR;\\n            }\\n\\n            return ((resCoefficient_ << EXPONENT_SIZE_DEBT_FACTOR) | resExponent_);\\n        }\\n    }\\n\\n    /// @dev divides a `bigNumber1` by `bigNumber2`.\\n    /// @dev For vault's use case (calculating connectionFactor_ = baseBranchDebtFactor / currentBranchDebtFactor) bigNumbers MUST always:\\n    ///      - have exponent size 15 bits and be >= 1 & <= 16384\\n    ///      - have coefficient size 35 bits and have 35th bit always 1 (when exponent > 0 BigMath numbers have max precision)\\n    ///        so coefficients must always be in range 17179869184 <= coefficient <= 34359738367.\\n    ///      - as a result of previous points, numbers must never be 0\\n    /// e.g. res = bigNumber1 / bigNumber2 = [(coe1, exp1) / (coe2, exp2)] << decimal\\n    ///          = ((coe1<<precision_)/coe2, exp1+decimal-exp2-precision_)\\n    /// @param bigNumber1          BigNumber format with coefficient and exponent\\n    /// @param bigNumber2          BigNumber format with coefficient and exponent\\n    /// @return                    BigNumber format with coefficient and exponent\\n    /// Returned connection factor can only ever be >= baseBranchDebtFactor (c = x*100/y with both x,y > 0 & x,y <= 100: c can only ever be >= x)\\n    function divBigNumber(uint256 bigNumber1, uint256 bigNumber2) internal pure returns (uint256) {\\n        unchecked {\\n            // (coefficient1_ << PRECISION) / coefficient2_\\n            uint256 resCoefficient_ = ((bigNumber1 >> EXPONENT_SIZE_DEBT_FACTOR) << PRECISION) /\\n                (bigNumber2 >> EXPONENT_SIZE_DEBT_FACTOR);\\n            // nominator at min 17179869184 << 64 = 316912650057057350374175801344. at max 34359738367 << 64 = 633825300095667956674642051072.\\n            // so min value resCoefficient_ 9223372037123211264 (64 bits) vs max 36893488146345361408 (fits in 65 bits)\\n\\n            // mostSigBit will be PRECISION + 1 or PRECISION\\n            uint256 overflowLen_ = ((resCoefficient_ >> PRECISION) == 1) ? (PRECISION + 1) : PRECISION;\\n            // Overflow will be PRECISION - COEFFICIENT_SIZE_DEBT_FACTOR or (PRECISION + 1) - COEFFICIENT_SIZE_DEBT_FACTOR\\n            // Meaning 64 - 35 = 29 or 65 - 35 = 30\\n            overflowLen_ = overflowLen_ - COEFFICIENT_SIZE_DEBT_FACTOR;\\n            resCoefficient_ = resCoefficient_ >> overflowLen_;\\n\\n            // exponent1_ will always be less than or equal to 16384\\n            // exponent2_ will always be less than or equal to 16384\\n            // Even if exponent2_ is 0 (not possible) & resExponent_ = DECIMALS_DEBT_FACTOR then also resExponent_ will be less than max limit, so no overflow\\n            // result exponent = (exponent1_ + DECIMALS_DEBT_FACTOR + overflowLen_) - (exponent2_ + PRECISION);\\n            uint256 resExponent_ = ((bigNumber1 & EXPONENT_MAX_DEBT_FACTOR) + // exponent1_\\n                DECIMALS_DEBT_FACTOR + // DECIMALS_DEBT_FACTOR is 100% as it is percentage value\\n                overflowLen_); // addition part resExponent_ here min 16414, max 32798\\n            // reuse overFlowLen_ variable for subtraction sum of exponent\\n            overflowLen_ = (bigNumber2 & EXPONENT_MAX_DEBT_FACTOR) + PRECISION; // subtraction part overflowLen_ here: min 65, max 16448\\n            if (resExponent_ > overflowLen_) {\\n                resExponent_ = resExponent_ - overflowLen_;\\n\\n                return ((resCoefficient_ << EXPONENT_SIZE_DEBT_FACTOR) | resExponent_);\\n            }\\n\\n            // Can happen if bigNumber1 exponent is < 35 (35+16384+29 = 16448) and bigNumber2 exponent is e.g. max 16384.\\n            // this would mean a branch with a normal big debt factor (bigNumber2) is merged into a base branch with an extremely small\\n            // debt factor (bigNumber1).\\n            // this should never happen anyway, but if it does better to revert than to continue with unknown effects.\\n            revert(); // connection factor should never become a BigNumber with exponent <= 0\\n        }\\n    }\\n}\\n\",\"keccak256\":\"0x1650e093b991c968e6e54fed394f1e81e81c2bdd2dfacf2e0d590514615a9bc9\",\"license\":\"BUSL-1.1\"},\"contracts/libraries/errorTypes.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nlibrary LibsErrorTypes {\\n    /***********************************|\\n    |         LiquidityCalcs            | \\n    |__________________________________*/\\n\\n    /// @notice thrown when supply or borrow exchange price is zero at calc token data (token not configured yet)\\n    uint256 internal constant LiquidityCalcs__ExchangePriceZero = 70001;\\n\\n    /// @notice thrown when rate data is set to a version that is not implemented\\n    uint256 internal constant LiquidityCalcs__UnsupportedRateVersion = 70002;\\n\\n    /***********************************|\\n    |           SafeTransfer            | \\n    |__________________________________*/\\n\\n    /// @notice thrown when safe transfer from for an ERC20 fails\\n    uint256 internal constant SafeTransfer__TransferFromFailed = 71001;\\n\\n    /// @notice thrown when safe transfer for an ERC20 fails\\n    uint256 internal constant SafeTransfer__TransferFailed = 71002;\\n}\\n\",\"keccak256\":\"0xfcd8d3b052c8e023b0db72cb9afe55c552d5a1ef4741dbcd1a494145f2d5ff62\",\"license\":\"BUSL-1.1\"},\"contracts/libraries/liquidityCalcs.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nimport { LibsErrorTypes as ErrorTypes } from \\\"./errorTypes.sol\\\";\\nimport { LiquiditySlotsLink } from \\\"./liquiditySlotsLink.sol\\\";\\nimport { BigMathMinified } from \\\"./bigMathMinified.sol\\\";\\n\\n/// @notice implements calculation methods used for Fluid liquidity such as updated exchange prices,\\n/// borrow rate, withdrawal / borrow limits, revenue amount.\\nlibrary LiquidityCalcs {\\n    error FluidLiquidityCalcsError(uint256 errorId_);\\n\\n    /// @notice emitted if the calculated borrow rate surpassed max borrow rate (16 bits) and was capped at maximum value 65535\\n    event BorrowRateMaxCap();\\n\\n    /// @dev constants as from Liquidity variables.sol\\n    uint256 internal constant EXCHANGE_PRICES_PRECISION = 1e12;\\n\\n    /// @dev Ignoring leap years\\n    uint256 internal constant SECONDS_PER_YEAR = 365 days;\\n    // constants used for BigMath conversion from and to storage\\n    uint256 internal constant DEFAULT_EXPONENT_SIZE = 8;\\n    uint256 internal constant DEFAULT_EXPONENT_MASK = 0xFF;\\n\\n    uint256 internal constant FOUR_DECIMALS = 1e4;\\n    uint256 internal constant TWELVE_DECIMALS = 1e12;\\n    uint256 internal constant X14 = 0x3fff;\\n    uint256 internal constant X15 = 0x7fff;\\n    uint256 internal constant X16 = 0xffff;\\n    uint256 internal constant X18 = 0x3ffff;\\n    uint256 internal constant X24 = 0xffffff;\\n    uint256 internal constant X33 = 0x1ffffffff;\\n    uint256 internal constant X64 = 0xffffffffffffffff;\\n\\n    ///////////////////////////////////////////////////////////////////////////\\n    //////////                  CALC EXCHANGE PRICES                  /////////\\n    ///////////////////////////////////////////////////////////////////////////\\n\\n    /// @dev calculates interest (exchange prices) for a token given its' exchangePricesAndConfig from storage.\\n    /// @param exchangePricesAndConfig_ exchange prices and config packed uint256 read from storage\\n    /// @return supplyExchangePrice_ updated supplyExchangePrice\\n    /// @return borrowExchangePrice_ updated borrowExchangePrice\\n    function calcExchangePrices(\\n        uint256 exchangePricesAndConfig_\\n    ) internal view returns (uint256 supplyExchangePrice_, uint256 borrowExchangePrice_) {\\n        // Extracting exchange prices\\n        supplyExchangePrice_ =\\n            (exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_SUPPLY_EXCHANGE_PRICE) &\\n            X64;\\n        borrowExchangePrice_ =\\n            (exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_BORROW_EXCHANGE_PRICE) &\\n            X64;\\n\\n        if (supplyExchangePrice_ == 0 || borrowExchangePrice_ == 0) {\\n            revert FluidLiquidityCalcsError(ErrorTypes.LiquidityCalcs__ExchangePriceZero);\\n        }\\n\\n        uint256 temp_ = exchangePricesAndConfig_ & X16; // temp_ = borrowRate\\n\\n        unchecked {\\n            // last timestamp can not be > current timestamp\\n            uint256 secondsSinceLastUpdate_ = block.timestamp -\\n                ((exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_LAST_TIMESTAMP) & X33);\\n\\n            uint256 borrowRatio_ = (exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_BORROW_RATIO) &\\n                X15;\\n            if (secondsSinceLastUpdate_ == 0 || temp_ == 0 || borrowRatio_ == 1) {\\n                // if no time passed, borrow rate is 0, or no raw borrowings: no exchange price update needed\\n                // (if borrowRatio_ == 1 means there is only borrowInterestFree, as first bit is 1 and rest is 0)\\n                return (supplyExchangePrice_, borrowExchangePrice_);\\n            }\\n\\n            // calculate new borrow exchange price.\\n            // formula borrowExchangePriceIncrease: previous price * borrow rate * secondsSinceLastUpdate_.\\n            // nominator is max uint112 (uint64 * uint16 * uint32). Divisor can not be 0.\\n            borrowExchangePrice_ +=\\n                (borrowExchangePrice_ * temp_ * secondsSinceLastUpdate_) /\\n                (SECONDS_PER_YEAR * FOUR_DECIMALS);\\n\\n            // FOR SUPPLY EXCHANGE PRICE:\\n            // all yield paid by borrowers (in mode with interest) goes to suppliers in mode with interest.\\n            // formula: previous price * supply rate * secondsSinceLastUpdate_.\\n            // where supply rate = (borrow rate  - revenueFee%) * ratioSupplyYield. And\\n            // ratioSupplyYield = utilization * supplyRatio * borrowRatio\\n            //\\n            // Example:\\n            // supplyRawInterest is 80, supplyInterestFree is 20. totalSupply is 100. BorrowedRawInterest is 50.\\n            // BorrowInterestFree is 10. TotalBorrow is 60. borrow rate 40%, revenueFee 10%.\\n            // yield is 10 (so half a year must have passed).\\n            // supplyRawInterest must become worth 89. totalSupply must become 109. BorrowedRawInterest must become 60.\\n            // borrowInterestFree must still be 10. supplyInterestFree still 20. totalBorrow 70.\\n            // supplyExchangePrice would have to go from 1 to 1,125 (+ 0.125). borrowExchangePrice from 1 to 1,2 (+0.2).\\n            // utilization is 60%. supplyRatio = 20 / 80 = 25% (only 80% of lenders receiving yield).\\n            // borrowRatio = 10 / 50 = 20% (only 83,333% of borrowers paying yield):\\n            // x of borrowers paying yield = 100% - (20 / (100 + 20)) = 100% - 16.6666666% = 83,333%.\\n            // ratioSupplyYield = 60% * 83,33333% * (100% + 20%) = 62,5%\\n            // supplyRate = (40% * (100% - 10%)) * = 36% * 62,5% = 22.5%\\n            // increase in supplyExchangePrice, assuming 100 as previous price.\\n            // 100 * 22,5% * 1/2 (half a year) = 0,1125.\\n            // cross-check supplyRawInterest worth = 80 * 1.1125 = 89. totalSupply worth = 89 + 20.\\n\\n            // -------------- 1. calculate ratioSupplyYield --------------------------------\\n            // step1: utilization * supplyRatio (or actually part of lenders receiving yield)\\n\\n            // temp_ => supplyRatio (in 1e2: 100% = 10_000; 1% = 100 -> max value 16_383)\\n            // if first bit 0 then ratio is supplyInterestFree / supplyWithInterest (supplyWithInterest is bigger)\\n            // else ratio is supplyWithInterest / supplyInterestFree (supplyInterestFree is bigger)\\n            temp_ = (exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_SUPPLY_RATIO) & X15;\\n\\n            if (temp_ == 1) {\\n                // if no raw supply: no exchange price update needed\\n                // (if supplyRatio_ == 1 means there is only supplyInterestFree, as first bit is 1 and rest is 0)\\n                return (supplyExchangePrice_, borrowExchangePrice_);\\n            }\\n\\n            // ratioSupplyYield precision is 1e27 as 100% for increased precision when supplyInterestFree > supplyWithInterest\\n            if (temp_ & 1 == 1) {\\n                // ratio is supplyWithInterest / supplyInterestFree (supplyInterestFree is bigger)\\n                temp_ = temp_ >> 1;\\n\\n                // Note: case where temp_ == 0 (only supplyInterestFree, no yield) already covered by early return\\n                // in the if statement a little above.\\n\\n                // based on above example but supplyRawInterest is 20, supplyInterestFree is 80. no fee.\\n                // supplyRawInterest must become worth 30. totalSupply must become 110.\\n                // supplyExchangePrice would have to go from 1 to 1,5. borrowExchangePrice from 1 to 1,2.\\n                // so ratioSupplyYield must come out as 2.5 (250%).\\n                // supplyRatio would be (20 * 10_000 / 80) = 2500. but must be inverted.\\n                temp_ = (1e27 * FOUR_DECIMALS) / temp_; // e.g. 1e31 / 2500 = 4e27. (* 1e27 for precision)\\n                // e.g. 5_000 * (1e27 + 4e27) / 1e27 = 25_000 (=250%).\\n                temp_ =\\n                    // utilization * (100% + 100% / supplyRatio)\\n                    (((exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_UTILIZATION) & X14) *\\n                        (1e27 + temp_)) / // extract utilization (max 16_383 so there is no way this can overflow).\\n                    (FOUR_DECIMALS);\\n                // max possible value of temp_ here is 16383 * (1e27 + 1e31) / 1e4 = ~1.64e31\\n            } else {\\n                // ratio is supplyInterestFree / supplyWithInterest (supplyWithInterest is bigger)\\n                temp_ = temp_ >> 1;\\n                // if temp_ == 0 then only supplyWithInterest => full yield. temp_ is already 0\\n\\n                // e.g. 5_000 * 10_000 + (20 * 10_000 / 80) / 10_000 = 5000 * 12500 / 10000 = 6250 (=62.5%).\\n                temp_ =\\n                    // 1e27 * utilization * (100% + supplyRatio) / 100%\\n                    (1e27 *\\n                        ((exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_UTILIZATION) & X14) * // extract utilization (max 16_383 so there is no way this can overflow).\\n                        (FOUR_DECIMALS + temp_)) /\\n                    (FOUR_DECIMALS * FOUR_DECIMALS);\\n                // max possible temp_ value: 1e27 * 16383 * 2e4 / 1e8 = 3.2766e27\\n            }\\n            // from here temp_ => ratioSupplyYield (utilization * supplyRatio part) scaled by 1e27. max possible value ~1.64e31\\n\\n            // step2 of ratioSupplyYield: add borrowRatio (only x% of borrowers paying yield)\\n            if (borrowRatio_ & 1 == 1) {\\n                // ratio is borrowWithInterest / borrowInterestFree (borrowInterestFree is bigger)\\n                borrowRatio_ = borrowRatio_ >> 1;\\n                // borrowRatio_ => x of total bororwers paying yield. scale to 1e27.\\n\\n                // Note: case where borrowRatio_ == 0 (only borrowInterestFree, no yield) already covered\\n                // at the beginning of the method by early return if `borrowRatio_ == 1`.\\n\\n                // based on above example but borrowRawInterest is 10, borrowInterestFree is 50. no fee. borrowRatio = 20%.\\n                // so only 16.66% of borrowers are paying yield. so the 100% - part of the formula is not needed.\\n                // x of borrowers paying yield = (borrowRatio / (100 + borrowRatio)) = 16.6666666%\\n                // borrowRatio_ => x of total bororwers paying yield. scale to 1e27.\\n                borrowRatio_ = (borrowRatio_ * 1e27) / (FOUR_DECIMALS + borrowRatio_);\\n                // max value here for borrowRatio_ is (1e31 / (1e4 + 1e4))= 5e26 (= 50% of borrowers paying yield).\\n            } else {\\n                // ratio is borrowInterestFree / borrowWithInterest (borrowWithInterest is bigger)\\n                borrowRatio_ = borrowRatio_ >> 1;\\n\\n                // borrowRatio_ => x of total bororwers paying yield. scale to 1e27.\\n                // x of borrowers paying yield = 100% - (borrowRatio / (100 + borrowRatio)) = 100% - 16.6666666% = 83,333%.\\n                borrowRatio_ = (1e27 - ((borrowRatio_ * 1e27) / (FOUR_DECIMALS + borrowRatio_)));\\n                // borrowRatio can never be > 100%. so max subtraction can be 100% - 100% / 200%.\\n                // or if borrowRatio_ is 0 -> 100% - 0. or if borrowRatio_ is 1 -> 100% - 1 / 101.\\n                // max value here for borrowRatio_ is 1e27 - 0 = 1e27 (= 100% of borrowers paying yield).\\n            }\\n\\n            // temp_ => ratioSupplyYield. scaled down from 1e25 = 1% each to normal percent precision 1e2 = 1%.\\n            // max nominator value is ~1.64e31 * 1e27 = 1.64e58. max result = 1.64e8\\n            temp_ = (FOUR_DECIMALS * temp_ * borrowRatio_) / 1e54;\\n\\n            // 2. calculate supply rate\\n            // temp_ => supply rate (borrow rate  - revenueFee%) * ratioSupplyYield.\\n            // division part is done in next step to increase precision. (divided by 2x FOUR_DECIMALS, fee + borrowRate)\\n            // Note that all calculation divisions for supplyExchangePrice are rounded down.\\n            // Note supply rate can be bigger than the borrowRate, e.g. if there are only few lenders with interest\\n            // but more suppliers not earning interest.\\n            temp_ = ((exchangePricesAndConfig_ & X16) * // borrow rate\\n                temp_ * // ratioSupplyYield\\n                (FOUR_DECIMALS - ((exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_FEE) & X14))); // revenueFee\\n            // fee can not be > 100%. max possible = 65535 * ~1.64e8 * 1e4 =~1.074774e17.\\n\\n            // 3. calculate increase in supply exchange price\\n            supplyExchangePrice_ += ((supplyExchangePrice_ * temp_ * secondsSinceLastUpdate_) /\\n                (SECONDS_PER_YEAR * FOUR_DECIMALS * FOUR_DECIMALS * FOUR_DECIMALS));\\n            // max possible nominator = max uint 64 * 1.074774e17 * max uint32 = ~8.52e45. Denominator can not be 0.\\n        }\\n    }\\n\\n    ///////////////////////////////////////////////////////////////////////////\\n    //////////                     CALC REVENUE                       /////////\\n    ///////////////////////////////////////////////////////////////////////////\\n\\n    /// @dev gets the `revenueAmount_` for a token given its' totalAmounts and exchangePricesAndConfig from storage\\n    /// and the current balance of the Fluid liquidity contract for the token.\\n    /// @param totalAmounts_ total amounts packed uint256 read from storage\\n    /// @param exchangePricesAndConfig_ exchange prices and config packed uint256 read from storage\\n    /// @param liquidityTokenBalance_   current balance of Liquidity contract (IERC20(token_).balanceOf(address(this)))\\n    /// @return revenueAmount_ collectable revenue amount\\n    function calcRevenue(\\n        uint256 totalAmounts_,\\n        uint256 exchangePricesAndConfig_,\\n        uint256 liquidityTokenBalance_\\n    ) internal view returns (uint256 revenueAmount_) {\\n        // @dev no need to super-optimize this method as it is only used by admin\\n\\n        // calculate the new exchange prices based on earned interest\\n        (uint256 supplyExchangePrice_, uint256 borrowExchangePrice_) = calcExchangePrices(exchangePricesAndConfig_);\\n\\n        // total supply = interest free + with interest converted from raw\\n        uint256 totalSupply_ = getTotalSupply(totalAmounts_, supplyExchangePrice_);\\n\\n        if (totalSupply_ > 0) {\\n            // available revenue: balanceOf(token) + totalBorrowings - totalLendings.\\n            revenueAmount_ = liquidityTokenBalance_ + getTotalBorrow(totalAmounts_, borrowExchangePrice_);\\n            // ensure there is no possible case because of rounding etc. where this would revert,\\n            // explicitly check if >\\n            revenueAmount_ = revenueAmount_ > totalSupply_ ? revenueAmount_ - totalSupply_ : 0;\\n            // Note: if utilization > 100% (totalSupply < totalBorrow), then all the amount above 100% utilization\\n            // can only be revenue.\\n        } else {\\n            // if supply is 0, then rest of balance can be withdrawn as revenue so that no amounts get stuck\\n            revenueAmount_ = liquidityTokenBalance_;\\n        }\\n    }\\n\\n    ///////////////////////////////////////////////////////////////////////////\\n    //////////                      CALC LIMITS                       /////////\\n    ///////////////////////////////////////////////////////////////////////////\\n\\n    /// @dev calculates withdrawal limit before an operate execution:\\n    /// amount of user supply that must stay supplied (not amount that can be withdrawn).\\n    /// i.e. if user has supplied 100m and can withdraw 5M, this method returns the 95M, not the withdrawable amount 5M\\n    /// @param userSupplyData_ user supply data packed uint256 from storage\\n    /// @param userSupply_ current user supply amount already extracted from `userSupplyData_` and converted from BigMath\\n    /// @return currentWithdrawalLimit_ current withdrawal limit updated for expansion since last interaction.\\n    ///         returned value is in raw for with interest mode, normal amount for interest free mode!\\n    function calcWithdrawalLimitBeforeOperate(\\n        uint256 userSupplyData_,\\n        uint256 userSupply_\\n    ) internal view returns (uint256 currentWithdrawalLimit_) {\\n        // @dev must support handling the case where timestamp is 0 (config is set but no interactions yet).\\n        // first tx where timestamp is 0 will enter `if (lastWithdrawalLimit_ == 0)` because lastWithdrawalLimit_ is not set yet.\\n        // returning max withdrawal allowed, which is not exactly right but doesn't matter because the first interaction must be\\n        // a deposit anyway. Important is that it would not revert.\\n\\n        // Note the first time a deposit brings the user supply amount to above the base withdrawal limit, the active limit\\n        // is the fully expanded limit immediately.\\n\\n        // extract last set withdrawal limit\\n        uint256 lastWithdrawalLimit_ = (userSupplyData_ >>\\n            LiquiditySlotsLink.BITS_USER_SUPPLY_PREVIOUS_WITHDRAWAL_LIMIT) & X64;\\n        lastWithdrawalLimit_ =\\n            (lastWithdrawalLimit_ >> DEFAULT_EXPONENT_SIZE) <<\\n            (lastWithdrawalLimit_ & DEFAULT_EXPONENT_MASK);\\n        if (lastWithdrawalLimit_ == 0) {\\n            // withdrawal limit is not activated. Max withdrawal allowed\\n            return 0;\\n        }\\n\\n        uint256 maxWithdrawableLimit_;\\n        uint256 temp_;\\n        unchecked {\\n            // extract max withdrawable percent of user supply and\\n            // calculate maximum withdrawable amount expandPercentage of user supply at full expansion duration elapsed\\n            // e.g.: if 10% expandPercentage, meaning 10% is withdrawable after full expandDuration has elapsed.\\n\\n            // userSupply_ needs to be atleast 1e73 to overflow max limit of ~1e77 in uint256 (no token in existence where this is possible).\\n            maxWithdrawableLimit_ =\\n                (((userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_EXPAND_PERCENT) & X14) * userSupply_) /\\n                FOUR_DECIMALS;\\n\\n            // time elapsed since last withdrawal limit was set (in seconds)\\n            // @dev last process timestamp is guaranteed to exist for withdrawal, as a supply must have happened before.\\n            // last timestamp can not be > current timestamp\\n            temp_ =\\n                block.timestamp -\\n                ((userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_LAST_UPDATE_TIMESTAMP) & X33);\\n        }\\n        // calculate withdrawable amount of expandPercent that is elapsed of expandDuration.\\n        // e.g. if 60% of expandDuration has elapsed, then user should be able to withdraw 6% of user supply, down to 94%.\\n        // Note: no explicit check for this needed, it is covered by setting minWithdrawalLimit_ if needed.\\n        temp_ =\\n            (maxWithdrawableLimit_ * temp_) /\\n            // extract expand duration: After this, decrement won't happen (user can withdraw 100% of withdraw limit)\\n            ((userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_EXPAND_DURATION) & X24); // expand duration can never be 0\\n        // calculate expanded withdrawal limit: last withdrawal limit - withdrawable amount.\\n        // Note: withdrawable amount here can grow bigger than userSupply if timeElapsed is a lot bigger than expandDuration,\\n        // which would cause the subtraction `lastWithdrawalLimit_ - withdrawableAmount_` to revert. In that case, set 0\\n        // which will cause minimum (fully expanded) withdrawal limit to be set in lines below.\\n        unchecked {\\n            // underflow explicitly checked & handled\\n            currentWithdrawalLimit_ = lastWithdrawalLimit_ > temp_ ? lastWithdrawalLimit_ - temp_ : 0;\\n            // calculate minimum withdrawal limit: minimum amount of user supply that must stay supplied at full expansion.\\n            // subtraction can not underflow as maxWithdrawableLimit_ is a percentage amount (<=100%) of userSupply_\\n            temp_ = userSupply_ - maxWithdrawableLimit_;\\n        }\\n        // if withdrawal limit is decreased below minimum then set minimum\\n        // (e.g. when more than expandDuration time has elapsed)\\n        if (temp_ > currentWithdrawalLimit_) {\\n            currentWithdrawalLimit_ = temp_;\\n        }\\n    }\\n\\n    /// @dev calculates withdrawal limit after an operate execution:\\n    /// amount of user supply that must stay supplied (not amount that can be withdrawn).\\n    /// i.e. if user has supplied 100m and can withdraw 5M, this method returns the 95M, not the withdrawable amount 5M\\n    /// @param userSupplyData_ user supply data packed uint256 from storage\\n    /// @param userSupply_ current user supply amount already extracted from `userSupplyData_` and added / subtracted with the executed operate amount\\n    /// @param newWithdrawalLimit_ current withdrawal limit updated for expansion since last interaction, result from `calcWithdrawalLimitBeforeOperate`\\n    /// @return withdrawalLimit_ updated withdrawal limit that should be written to storage. returned value is in\\n    ///                          raw for with interest mode, normal amount for interest free mode!\\n    function calcWithdrawalLimitAfterOperate(\\n        uint256 userSupplyData_,\\n        uint256 userSupply_,\\n        uint256 newWithdrawalLimit_\\n    ) internal pure returns (uint256) {\\n        // temp_ => base withdrawal limit. below this, maximum withdrawals are allowed\\n        uint256 temp_ = (userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_BASE_WITHDRAWAL_LIMIT) & X18;\\n        temp_ = (temp_ >> DEFAULT_EXPONENT_SIZE) << (temp_ & DEFAULT_EXPONENT_MASK);\\n\\n        // if user supply is below base limit then max withdrawals are allowed\\n        if (userSupply_ < temp_) {\\n            return 0;\\n        }\\n        // temp_ => withdrawal limit expandPercent (is in 1e2 decimals)\\n        temp_ = (userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_EXPAND_PERCENT) & X14;\\n        unchecked {\\n            // temp_ => minimum withdrawal limit: userSupply - max withdrawable limit (userSupply * expandPercent))\\n            // userSupply_ needs to be atleast 1e73 to overflow max limit of ~1e77 in uint256 (no token in existence where this is possible).\\n            // subtraction can not underflow as maxWithdrawableLimit_ is a percentage amount (<=100%) of userSupply_\\n            temp_ = userSupply_ - ((userSupply_ * temp_) / FOUR_DECIMALS);\\n        }\\n        // if new (before operation) withdrawal limit is less than minimum limit then set minimum limit.\\n        // e.g. can happen on new deposits. withdrawal limit is instantly fully expanded in a scenario where\\n        // increased deposit amount outpaces withrawals.\\n        if (temp_ > newWithdrawalLimit_) {\\n            return temp_;\\n        }\\n        return newWithdrawalLimit_;\\n    }\\n\\n    /// @dev calculates borrow limit before an operate execution:\\n    /// total amount user borrow can reach (not borrowable amount in current operation).\\n    /// i.e. if user has borrowed 50M and can still borrow 5M, this method returns the total 55M, not the borrowable amount 5M\\n    /// @param userBorrowData_ user borrow data packed uint256 from storage\\n    /// @param userBorrow_ current user borrow amount already extracted from `userBorrowData_`\\n    /// @return currentBorrowLimit_ current borrow limit updated for expansion since last interaction. returned value is in\\n    ///                             raw for with interest mode, normal amount for interest free mode!\\n    function calcBorrowLimitBeforeOperate(\\n        uint256 userBorrowData_,\\n        uint256 userBorrow_\\n    ) internal view returns (uint256 currentBorrowLimit_) {\\n        // @dev must support handling the case where timestamp is 0 (config is set but no interactions yet) -> base limit.\\n        // first tx where timestamp is 0 will enter `if (maxExpandedBorrowLimit_ < baseBorrowLimit_)` because `userBorrow_` and thus\\n        // `maxExpansionLimit_` and thus `maxExpandedBorrowLimit_` is 0 and `baseBorrowLimit_` can not be 0.\\n\\n        // temp_ = extract borrow expand percent (is in 1e2 decimals)\\n        uint256 temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_EXPAND_PERCENT) & X14;\\n\\n        uint256 maxExpansionLimit_;\\n        uint256 maxExpandedBorrowLimit_;\\n        unchecked {\\n            // calculate max expansion limit: Max amount limit can expand to since last interaction\\n            // userBorrow_ needs to be atleast 1e73 to overflow max limit of ~1e77 in uint256 (no token in existence where this is possible).\\n            maxExpansionLimit_ = ((userBorrow_ * temp_) / FOUR_DECIMALS);\\n\\n            // calculate max borrow limit: Max point limit can increase to since last interaction\\n            maxExpandedBorrowLimit_ = userBorrow_ + maxExpansionLimit_;\\n        }\\n\\n        // currentBorrowLimit_ = extract base borrow limit\\n        currentBorrowLimit_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_BASE_BORROW_LIMIT) & X18;\\n        currentBorrowLimit_ =\\n            (currentBorrowLimit_ >> DEFAULT_EXPONENT_SIZE) <<\\n            (currentBorrowLimit_ & DEFAULT_EXPONENT_MASK);\\n\\n        if (maxExpandedBorrowLimit_ < currentBorrowLimit_) {\\n            return currentBorrowLimit_;\\n        }\\n        // time elapsed since last borrow limit was set (in seconds)\\n        unchecked {\\n            // temp_ = timeElapsed_ (last timestamp can not be > current timestamp)\\n            temp_ =\\n                block.timestamp -\\n                ((userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_LAST_UPDATE_TIMESTAMP) & X33); // extract last udpate timestamp\\n        }\\n\\n        // currentBorrowLimit_ = expandedBorrowableAmount + extract last set borrow limit\\n        currentBorrowLimit_ =\\n            // calculate borrow limit expansion since last interaction for `expandPercent` that is elapsed of `expandDuration`.\\n            // divisor is extract expand duration (after this, full expansion to expandPercentage happened).\\n            ((maxExpansionLimit_ * temp_) /\\n                ((userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_EXPAND_DURATION) & X24)) + // expand duration can never be 0\\n            //  extract last set borrow limit\\n            BigMathMinified.fromBigNumber(\\n                (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_PREVIOUS_BORROW_LIMIT) & X64,\\n                DEFAULT_EXPONENT_SIZE,\\n                DEFAULT_EXPONENT_MASK\\n            );\\n\\n        // if timeElapsed is bigger than expandDuration, new borrow limit would be > max expansion,\\n        // so set to `maxExpandedBorrowLimit_` in that case.\\n        // also covers the case where last process timestamp = 0 (timeElapsed would simply be very big)\\n        if (currentBorrowLimit_ > maxExpandedBorrowLimit_) {\\n            currentBorrowLimit_ = maxExpandedBorrowLimit_;\\n        }\\n        // temp_ = extract hard max borrow limit. Above this user can never borrow (not expandable above)\\n        temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_MAX_BORROW_LIMIT) & X18;\\n        temp_ = (temp_ >> DEFAULT_EXPONENT_SIZE) << (temp_ & DEFAULT_EXPONENT_MASK);\\n\\n        if (currentBorrowLimit_ > temp_) {\\n            currentBorrowLimit_ = temp_;\\n        }\\n    }\\n\\n    /// @dev calculates borrow limit after an operate execution:\\n    /// total amount user borrow can reach (not borrowable amount in current operation).\\n    /// i.e. if user has borrowed 50M and can still borrow 5M, this method returns the total 55M, not the borrowable amount 5M\\n    /// @param userBorrowData_ user borrow data packed uint256 from storage\\n    /// @param userBorrow_ current user borrow amount already extracted from `userBorrowData_` and added / subtracted with the executed operate amount\\n    /// @param newBorrowLimit_ current borrow limit updated for expansion since last interaction, result from `calcBorrowLimitBeforeOperate`\\n    /// @return borrowLimit_ updated borrow limit that should be written to storage.\\n    ///                      returned value is in raw for with interest mode, normal amount for interest free mode!\\n    function calcBorrowLimitAfterOperate(\\n        uint256 userBorrowData_,\\n        uint256 userBorrow_,\\n        uint256 newBorrowLimit_\\n    ) internal pure returns (uint256 borrowLimit_) {\\n        // temp_ = extract borrow expand percent\\n        uint256 temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_EXPAND_PERCENT) & X14; // (is in 1e2 decimals)\\n\\n        unchecked {\\n            // borrowLimit_ = calculate maximum borrow limit at full expansion.\\n            // userBorrow_ needs to be at least 1e73 to overflow max limit of ~1e77 in uint256 (no token in existence where this is possible).\\n            borrowLimit_ = userBorrow_ + ((userBorrow_ * temp_) / FOUR_DECIMALS);\\n        }\\n\\n        // temp_ = extract base borrow limit\\n        temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_BASE_BORROW_LIMIT) & X18;\\n        temp_ = (temp_ >> DEFAULT_EXPONENT_SIZE) << (temp_ & DEFAULT_EXPONENT_MASK);\\n\\n        if (borrowLimit_ < temp_) {\\n            // below base limit, borrow limit is always base limit\\n            return temp_;\\n        }\\n        // temp_ = extract hard max borrow limit. Above this user can never borrow (not expandable above)\\n        temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_MAX_BORROW_LIMIT) & X18;\\n        temp_ = (temp_ >> DEFAULT_EXPONENT_SIZE) << (temp_ & DEFAULT_EXPONENT_MASK);\\n\\n        // make sure fully expanded borrow limit is not above hard max borrow limit\\n        if (borrowLimit_ > temp_) {\\n            borrowLimit_ = temp_;\\n        }\\n        // if new borrow limit (from before operate) is > max borrow limit, set max borrow limit.\\n        // (e.g. on a repay shrinking instantly to fully expanded borrow limit from new borrow amount. shrinking is instant)\\n        if (newBorrowLimit_ > borrowLimit_) {\\n            return borrowLimit_;\\n        }\\n        return newBorrowLimit_;\\n    }\\n\\n    ///////////////////////////////////////////////////////////////////////////\\n    //////////                      CALC RATES                        /////////\\n    ///////////////////////////////////////////////////////////////////////////\\n\\n    /// @dev Calculates new borrow rate from utilization for a token\\n    /// @param rateData_ rate data packed uint256 from storage for the token\\n    /// @param utilization_ totalBorrow / totalSupply. 1e4 = 100% utilization\\n    /// @return rate_ rate for that particular token in 1e2 precision (e.g. 5% rate = 500)\\n    function calcBorrowRateFromUtilization(uint256 rateData_, uint256 utilization_) internal returns (uint256 rate_) {\\n        // extract rate version: 4 bits (0xF) starting from bit 0\\n        uint256 rateVersion_ = (rateData_ & 0xF);\\n\\n        if (rateVersion_ == 1) {\\n            rate_ = calcRateV1(rateData_, utilization_);\\n        } else if (rateVersion_ == 2) {\\n            rate_ = calcRateV2(rateData_, utilization_);\\n        } else {\\n            revert FluidLiquidityCalcsError(ErrorTypes.LiquidityCalcs__UnsupportedRateVersion);\\n        }\\n\\n        if (rate_ > X16) {\\n            // hard cap for borrow rate at maximum value 16 bits (65535) to make sure it does not overflow storage space.\\n            // this is unlikely to ever happen if configs stay within expected levels.\\n            rate_ = X16;\\n            // emit event to more easily become aware\\n            emit BorrowRateMaxCap();\\n        }\\n    }\\n\\n    /// @dev calculates the borrow rate based on utilization for rate data version 1 (with one kink) in 1e2 precision\\n    /// @param rateData_ rate data packed uint256 from storage for the token\\n    /// @param utilization_  in 1e2 (100% = 1e4)\\n    /// @return rate_ rate in 1e2 precision\\n    function calcRateV1(uint256 rateData_, uint256 utilization_) internal pure returns (uint256 rate_) {\\n        /// For rate v1 (one kink) ------------------------------------------------------\\n        /// Next 16  bits =>  4 - 19 => Rate at utilization 0% (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Next 16  bits =>  20- 35 => Utilization at kink1 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Next 16  bits =>  36- 51 => Rate at utilization kink1 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Next 16  bits =>  52- 67 => Rate at utilization 100% (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Last 188 bits =>  68-255 => blank, might come in use in future\\n\\n        // y = mx + c.\\n        // y is borrow rate\\n        // x is utilization\\n        // m = slope (m can be 0 but never negative)\\n        // c is constant (c can be negative)\\n\\n        uint256 y1_;\\n        uint256 y2_;\\n        uint256 x1_;\\n        uint256 x2_;\\n\\n        // extract kink1: 16 bits (0xFFFF) starting from bit 20\\n        // kink is in 1e2, same as utilization, so no conversion needed for direct comparison of the two\\n        uint256 kink1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_UTILIZATION_AT_KINK) & X16;\\n        if (utilization_ < kink1_) {\\n            // if utilization is less than kink\\n            y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_ZERO) & X16;\\n            y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_KINK) & X16;\\n            x1_ = 0; // 0%\\n            x2_ = kink1_;\\n        } else {\\n            // else utilization is greater than kink\\n            y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_KINK) & X16;\\n            y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_MAX) & X16;\\n            x1_ = kink1_;\\n            x2_ = FOUR_DECIMALS; // 100%\\n        }\\n\\n        int256 constant_;\\n        uint256 slope_;\\n        unchecked {\\n            // calculating slope with twelve decimal precision. m = (y2 - y1) / (x2 - x1).\\n            // utilization of x2 can not be <= utilization of x1 (so no underflow or 0 divisor) and rate at y2 can not be < rate at y1\\n            // y is in 1e2 so can not overflow when multiplied with TWELVE_DECIMALS\\n            slope_ = ((y2_ - y1_) * TWELVE_DECIMALS) / (x2_ - x1_);\\n\\n            // calculating constant at 12 decimal precision. slope is already in 12 decimal hence only multiple with y1. c = y - mx.\\n            // maximum y1_ value is 65535. 65535 * 1e12 can not overflow int256\\n            // maximum slope is 65535 - 0 * TWELVE_DECIMALS / 1 = 65535 * 1e12;\\n            // maximum x1_ is 100% (9_999 actually) => slope_ * x1_ can not overflow int256\\n            // subtraction most extreme case would be  0 - max value slope_ * x1_ => can not underflow int256\\n            constant_ = int256(y1_ * TWELVE_DECIMALS) - int256(slope_ * x1_);\\n\\n            // calculating new borrow rate\\n            // - slope_ max value is 65535 * 1e12,\\n            // - utilization max value is let's say 500% (extreme case where borrow rate increases borrow amount without new supply)\\n            // - constant max value is 65535 * 1e12\\n            // so max values are 65535 * 1e12 * 50_000 + 65535 * 1e12 -> 3.2768*10^21, which easily fits int256\\n            // divisor TWELVE_DECIMALS can not be 0\\n            rate_ = (uint256(int256(slope_ * utilization_) + constant_)) / TWELVE_DECIMALS;\\n        }\\n    }\\n\\n    /// @dev calculates the borrow rate based on utilization for rate data version 2 (with two kinks) in 1e4 precision\\n    /// @param rateData_ rate data packed uint256 from storage for the token\\n    /// @param utilization_  in 1e2 (100% = 1e4)\\n    /// @return rate_ rate in 1e4 precision\\n    function calcRateV2(uint256 rateData_, uint256 utilization_) internal pure returns (uint256 rate_) {\\n        /// For rate v2 (two kinks) -----------------------------------------------------\\n        /// Next 16  bits =>  4 - 19 => Rate at utilization 0% (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Next 16  bits =>  20- 35 => Utilization at kink1 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Next 16  bits =>  36- 51 => Rate at utilization kink1 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Next 16  bits =>  52- 67 => Utilization at kink2 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Next 16  bits =>  68- 83 => Rate at utilization kink2 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Next 16  bits =>  84- 99 => Rate at utilization 100% (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)\\n        /// Last 156 bits => 100-255 => blank, might come in use in future\\n\\n        // y = mx + c.\\n        // y is borrow rate\\n        // x is utilization\\n        // m = slope (m can be 0 but never negative)\\n        // c is constant (c can be negative)\\n\\n        uint256 y1_;\\n        uint256 y2_;\\n        uint256 x1_;\\n        uint256 x2_;\\n\\n        // extract kink1: 16 bits (0xFFFF) starting from bit 20\\n        // kink is in 1e2, same as utilization, so no conversion needed for direct comparison of the two\\n        uint256 kink1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_UTILIZATION_AT_KINK1) & X16;\\n        if (utilization_ < kink1_) {\\n            // if utilization is less than kink1\\n            y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_ZERO) & X16;\\n            y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK1) & X16;\\n            x1_ = 0; // 0%\\n            x2_ = kink1_;\\n        } else {\\n            // extract kink2: 16 bits (0xFFFF) starting from bit 52\\n            uint256 kink2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_UTILIZATION_AT_KINK2) & X16;\\n            if (utilization_ < kink2_) {\\n                // if utilization is less than kink2\\n                y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK1) & X16;\\n                y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK2) & X16;\\n                x1_ = kink1_;\\n                x2_ = kink2_;\\n            } else {\\n                // else utilization is greater than kink2\\n                y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK2) & X16;\\n                y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_MAX) & X16;\\n                x1_ = kink2_;\\n                x2_ = FOUR_DECIMALS;\\n            }\\n        }\\n\\n        int256 constant_;\\n        uint256 slope_;\\n        unchecked {\\n            // calculating slope with twelve decimal precision. m = (y2 - y1) / (x2 - x1).\\n            // utilization of x2 can not be <= utilization of x1 (so no underflow or 0 divisor) and rate at y2 can not be < rate at y1\\n            // y is in 1e2 so can not overflow when multiplied with TWELVE_DECIMALS\\n            slope_ = ((y2_ - y1_) * TWELVE_DECIMALS) / (x2_ - x1_);\\n\\n            // calculating constant at 12 decimal precision. slope is already in 12 decimal hence only multiple with y1. c = y - mx.\\n            // maximum y1_ value is 65535. 65535 * 1e12 can not overflow int256\\n            // maximum slope is 65535 - 0 * TWELVE_DECIMALS / 1 = 65535 * 1e12;\\n            // maximum x1_ is 100% (9_999 actually) => slope_ * x1_ can not overflow int256\\n            // subtraction most extreme case would be  0 - max value slope_ * x1_ => can not underflow int256\\n            constant_ = int256(y1_ * TWELVE_DECIMALS) - int256(slope_ * x1_);\\n\\n            // calculating new borrow rate\\n            // - slope_ max value is 65535 * 1e12,\\n            // - utilization max value is let's say 500% (extreme case where borrow rate increases borrow amount without new supply)\\n            // - constant max value is 65535 * 1e12\\n            // so max values are 65535 * 1e12 * 50_000 + 65535 * 1e12 -> 3.2768*10^21, which easily fits int256\\n            // divisor TWELVE_DECIMALS can not be 0\\n            rate_ = (uint256(int256(slope_ * utilization_) + constant_)) / TWELVE_DECIMALS;\\n        }\\n    }\\n\\n    /// @dev reads the total supply out of Liquidity packed storage `totalAmounts_` for `supplyExchangePrice_`\\n    function getTotalSupply(\\n        uint256 totalAmounts_,\\n        uint256 supplyExchangePrice_\\n    ) internal pure returns (uint256 totalSupply_) {\\n        // totalSupply_ => supplyInterestFree\\n        totalSupply_ = (totalAmounts_ >> LiquiditySlotsLink.BITS_TOTAL_AMOUNTS_SUPPLY_INTEREST_FREE) & X64;\\n        totalSupply_ = (totalSupply_ >> DEFAULT_EXPONENT_SIZE) << (totalSupply_ & DEFAULT_EXPONENT_MASK);\\n\\n        uint256 totalSupplyRaw_ = totalAmounts_ & X64; // no shifting as supplyRaw is first 64 bits\\n        totalSupplyRaw_ = (totalSupplyRaw_ >> DEFAULT_EXPONENT_SIZE) << (totalSupplyRaw_ & DEFAULT_EXPONENT_MASK);\\n\\n        // totalSupply = supplyInterestFree + supplyRawInterest normalized from raw\\n        totalSupply_ += ((totalSupplyRaw_ * supplyExchangePrice_) / EXCHANGE_PRICES_PRECISION);\\n    }\\n\\n    /// @dev reads the total borrow out of Liquidity packed storage `totalAmounts_` for `borrowExchangePrice_`\\n    function getTotalBorrow(\\n        uint256 totalAmounts_,\\n        uint256 borrowExchangePrice_\\n    ) internal pure returns (uint256 totalBorrow_) {\\n        // totalBorrow_ => borrowInterestFree\\n        // no & mask needed for borrow interest free as it occupies the last bits in the storage slot\\n        totalBorrow_ = (totalAmounts_ >> LiquiditySlotsLink.BITS_TOTAL_AMOUNTS_BORROW_INTEREST_FREE);\\n        totalBorrow_ = (totalBorrow_ >> DEFAULT_EXPONENT_SIZE) << (totalBorrow_ & DEFAULT_EXPONENT_MASK);\\n\\n        uint256 totalBorrowRaw_ = (totalAmounts_ >> LiquiditySlotsLink.BITS_TOTAL_AMOUNTS_BORROW_WITH_INTEREST) & X64;\\n        totalBorrowRaw_ = (totalBorrowRaw_ >> DEFAULT_EXPONENT_SIZE) << (totalBorrowRaw_ & DEFAULT_EXPONENT_MASK);\\n\\n        // totalBorrow = borrowInterestFree + borrowRawInterest normalized from raw\\n        totalBorrow_ += ((totalBorrowRaw_ * borrowExchangePrice_) / EXCHANGE_PRICES_PRECISION);\\n    }\\n}\\n\",\"keccak256\":\"0x1abba442b74ee50d039a5491aae9e7a156a62f783363ce545e44ee82cc699f27\",\"license\":\"BUSL-1.1\"},\"contracts/libraries/liquiditySlotsLink.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\n/// @notice library that helps in reading / working with storage slot data of Fluid Liquidity.\\n/// @dev as all data for Fluid Liquidity is internal, any data must be fetched directly through manual\\n/// slot reading through this library or, if gas usage is less important, through the FluidLiquidityResolver.\\nlibrary LiquiditySlotsLink {\\n    /// @dev storage slot for status at Liquidity\\n    uint256 internal constant LIQUIDITY_STATUS_SLOT = 1;\\n    /// @dev storage slot for auths mapping at Liquidity\\n    uint256 internal constant LIQUIDITY_AUTHS_MAPPING_SLOT = 2;\\n    /// @dev storage slot for guardians mapping at Liquidity\\n    uint256 internal constant LIQUIDITY_GUARDIANS_MAPPING_SLOT = 3;\\n    /// @dev storage slot for user class mapping at Liquidity\\n    uint256 internal constant LIQUIDITY_USER_CLASS_MAPPING_SLOT = 4;\\n    /// @dev storage slot for exchangePricesAndConfig mapping at Liquidity\\n    uint256 internal constant LIQUIDITY_EXCHANGE_PRICES_MAPPING_SLOT = 5;\\n    /// @dev storage slot for rateData mapping at Liquidity\\n    uint256 internal constant LIQUIDITY_RATE_DATA_MAPPING_SLOT = 6;\\n    /// @dev storage slot for totalAmounts mapping at Liquidity\\n    uint256 internal constant LIQUIDITY_TOTAL_AMOUNTS_MAPPING_SLOT = 7;\\n    /// @dev storage slot for user supply double mapping at Liquidity\\n    uint256 internal constant LIQUIDITY_USER_SUPPLY_DOUBLE_MAPPING_SLOT = 8;\\n    /// @dev storage slot for user borrow double mapping at Liquidity\\n    uint256 internal constant LIQUIDITY_USER_BORROW_DOUBLE_MAPPING_SLOT = 9;\\n    /// @dev storage slot for listed tokens array at Liquidity\\n    uint256 internal constant LIQUIDITY_LISTED_TOKENS_ARRAY_SLOT = 10;\\n\\n    // --------------------------------\\n    // @dev stacked uint256 storage slots bits position data for each:\\n\\n    // ExchangePricesAndConfig\\n    uint256 internal constant BITS_EXCHANGE_PRICES_BORROW_RATE = 0;\\n    uint256 internal constant BITS_EXCHANGE_PRICES_FEE = 16;\\n    uint256 internal constant BITS_EXCHANGE_PRICES_UTILIZATION = 30;\\n    uint256 internal constant BITS_EXCHANGE_PRICES_UPDATE_THRESHOLD = 44;\\n    uint256 internal constant BITS_EXCHANGE_PRICES_LAST_TIMESTAMP = 58;\\n    uint256 internal constant BITS_EXCHANGE_PRICES_SUPPLY_EXCHANGE_PRICE = 91;\\n    uint256 internal constant BITS_EXCHANGE_PRICES_BORROW_EXCHANGE_PRICE = 155;\\n    uint256 internal constant BITS_EXCHANGE_PRICES_SUPPLY_RATIO = 219;\\n    uint256 internal constant BITS_EXCHANGE_PRICES_BORROW_RATIO = 234;\\n\\n    // RateData:\\n    uint256 internal constant BITS_RATE_DATA_VERSION = 0;\\n    // RateData: V1\\n    uint256 internal constant BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_ZERO = 4;\\n    uint256 internal constant BITS_RATE_DATA_V1_UTILIZATION_AT_KINK = 20;\\n    uint256 internal constant BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_KINK = 36;\\n    uint256 internal constant BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_MAX = 52;\\n    // RateData: V2\\n    uint256 internal constant BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_ZERO = 4;\\n    uint256 internal constant BITS_RATE_DATA_V2_UTILIZATION_AT_KINK1 = 20;\\n    uint256 internal constant BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK1 = 36;\\n    uint256 internal constant BITS_RATE_DATA_V2_UTILIZATION_AT_KINK2 = 52;\\n    uint256 internal constant BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK2 = 68;\\n    uint256 internal constant BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_MAX = 84;\\n\\n    // TotalAmounts\\n    uint256 internal constant BITS_TOTAL_AMOUNTS_SUPPLY_WITH_INTEREST = 0;\\n    uint256 internal constant BITS_TOTAL_AMOUNTS_SUPPLY_INTEREST_FREE = 64;\\n    uint256 internal constant BITS_TOTAL_AMOUNTS_BORROW_WITH_INTEREST = 128;\\n    uint256 internal constant BITS_TOTAL_AMOUNTS_BORROW_INTEREST_FREE = 192;\\n\\n    // UserSupplyData\\n    uint256 internal constant BITS_USER_SUPPLY_MODE = 0;\\n    uint256 internal constant BITS_USER_SUPPLY_AMOUNT = 1;\\n    uint256 internal constant BITS_USER_SUPPLY_PREVIOUS_WITHDRAWAL_LIMIT = 65;\\n    uint256 internal constant BITS_USER_SUPPLY_LAST_UPDATE_TIMESTAMP = 129;\\n    uint256 internal constant BITS_USER_SUPPLY_EXPAND_PERCENT = 162;\\n    uint256 internal constant BITS_USER_SUPPLY_EXPAND_DURATION = 176;\\n    uint256 internal constant BITS_USER_SUPPLY_BASE_WITHDRAWAL_LIMIT = 200;\\n    uint256 internal constant BITS_USER_SUPPLY_IS_PAUSED = 255;\\n\\n    // UserBorrowData\\n    uint256 internal constant BITS_USER_BORROW_MODE = 0;\\n    uint256 internal constant BITS_USER_BORROW_AMOUNT = 1;\\n    uint256 internal constant BITS_USER_BORROW_PREVIOUS_BORROW_LIMIT = 65;\\n    uint256 internal constant BITS_USER_BORROW_LAST_UPDATE_TIMESTAMP = 129;\\n    uint256 internal constant BITS_USER_BORROW_EXPAND_PERCENT = 162;\\n    uint256 internal constant BITS_USER_BORROW_EXPAND_DURATION = 176;\\n    uint256 internal constant BITS_USER_BORROW_BASE_BORROW_LIMIT = 200;\\n    uint256 internal constant BITS_USER_BORROW_MAX_BORROW_LIMIT = 218;\\n    uint256 internal constant BITS_USER_BORROW_IS_PAUSED = 255;\\n\\n    // --------------------------------\\n\\n    /// @notice Calculating the slot ID for Liquidity contract for single mapping at `slot_` for `key_`\\n    function calculateMappingStorageSlot(uint256 slot_, address key_) internal pure returns (bytes32) {\\n        return keccak256(abi.encode(key_, slot_));\\n    }\\n\\n    /// @notice Calculating the slot ID for Liquidity contract for double mapping at `slot_` for `key1_` and `key2_`\\n    function calculateDoubleMappingStorageSlot(\\n        uint256 slot_,\\n        address key1_,\\n        address key2_\\n    ) internal pure returns (bytes32) {\\n        bytes32 intermediateSlot_ = keccak256(abi.encode(key1_, slot_));\\n        return keccak256(abi.encode(key2_, intermediateSlot_));\\n    }\\n}\\n\",\"keccak256\":\"0x85725ce90bbeb00541715fe58fb213b96706515e9eafdae357657995e9ac147d\",\"license\":\"BUSL-1.1\"},\"contracts/libraries/safeTransfer.sol\":{\"content\":\"// SPDX-License-Identifier: MIT OR Apache-2.0\\npragma solidity 0.8.21;\\n\\nimport { LibsErrorTypes as ErrorTypes } from \\\"./errorTypes.sol\\\";\\n\\n/// @notice provides minimalistic methods for safe transfers, e.g. ERC20 safeTransferFrom\\nlibrary SafeTransfer {\\n    error FluidSafeTransferError(uint256 errorId_);\\n\\n    /// @dev Transfer `amount_` of `token_` from `from_` to `to_`, spending the approval given by `from_` to the\\n    /// calling contract. If `token_` returns no value, non-reverting calls are assumed to be successful.\\n    /// Minimally modified from Solmate SafeTransferLib (address as input param for token, Custom Error):\\n    /// https://github.com/transmissions11/solmate/blob/50e15bb566f98b7174da9b0066126a4c3e75e0fd/src/utils/SafeTransferLib.sol#L31-L63\\n    function safeTransferFrom(address token_, address from_, address to_, uint256 amount_) internal {\\n        bool success_;\\n\\n        /// @solidity memory-safe-assembly\\n        assembly {\\n            // Get a pointer to some free memory.\\n            let freeMemoryPointer := mload(0x40)\\n\\n            // Write the abi-encoded calldata into memory, beginning with the function selector.\\n            mstore(freeMemoryPointer, 0x23b872dd00000000000000000000000000000000000000000000000000000000)\\n            mstore(add(freeMemoryPointer, 4), and(from_, 0xffffffffffffffffffffffffffffffffffffffff)) // Append and mask the \\\"from_\\\" argument.\\n            mstore(add(freeMemoryPointer, 36), and(to_, 0xffffffffffffffffffffffffffffffffffffffff)) // Append and mask the \\\"to_\\\" argument.\\n            mstore(add(freeMemoryPointer, 68), amount_) // Append the \\\"amount_\\\" argument. Masking not required as it's a full 32 byte type.\\n\\n            success_ := and(\\n                // Set success to whether the call reverted, if not we check it either\\n                // returned exactly 1 (can't just be non-zero data), or had no return data.\\n                or(and(eq(mload(0), 1), gt(returndatasize(), 31)), iszero(returndatasize())),\\n                // We use 100 because the length of our calldata totals up like so: 4 + 32 * 3.\\n                // We use 0 and 32 to copy up to 32 bytes of return data into the scratch space.\\n                // Counterintuitively, this call must be positioned second to the or() call in the\\n                // surrounding and() call or else returndatasize() will be zero during the computation.\\n                call(gas(), token_, 0, freeMemoryPointer, 100, 0, 32)\\n            )\\n        }\\n\\n        if (!success_) {\\n            revert FluidSafeTransferError(ErrorTypes.SafeTransfer__TransferFromFailed);\\n        }\\n    }\\n\\n    /// @dev Transfer `amount_` of `token_` to `to_`.\\n    /// If `token_` returns no value, non-reverting calls are assumed to be successful.\\n    /// Minimally modified from Solmate SafeTransferLib (address as input param for token, Custom Error):\\n    /// https://github.com/transmissions11/solmate/blob/50e15bb566f98b7174da9b0066126a4c3e75e0fd/src/utils/SafeTransferLib.sol#L65-L95\\n    function safeTransfer(address token_, address to_, uint256 amount_) internal {\\n        bool success_;\\n\\n        /// @solidity memory-safe-assembly\\n        assembly {\\n            // Get a pointer to some free memory.\\n            let freeMemoryPointer := mload(0x40)\\n\\n            // Write the abi-encoded calldata into memory, beginning with the function selector.\\n            mstore(freeMemoryPointer, 0xa9059cbb00000000000000000000000000000000000000000000000000000000)\\n            mstore(add(freeMemoryPointer, 4), and(to_, 0xffffffffffffffffffffffffffffffffffffffff)) // Append and mask the \\\"to_\\\" argument.\\n            mstore(add(freeMemoryPointer, 36), amount_) // Append the \\\"amount_\\\" argument. Masking not required as it's a full 32 byte type.\\n\\n            success_ := and(\\n                // Set success to whether the call reverted, if not we check it either\\n                // returned exactly 1 (can't just be non-zero data), or had no return data.\\n                or(and(eq(mload(0), 1), gt(returndatasize(), 31)), iszero(returndatasize())),\\n                // We use 68 because the length of our calldata totals up like so: 4 + 32 * 2.\\n                // We use 0 and 32 to copy up to 32 bytes of return data into the scratch space.\\n                // Counterintuitively, this call must be positioned second to the or() call in the\\n                // surrounding and() call or else returndatasize() will be zero during the computation.\\n                call(gas(), token_, 0, freeMemoryPointer, 68, 0, 32)\\n            )\\n        }\\n\\n        if (!success_) {\\n            revert FluidSafeTransferError(ErrorTypes.SafeTransfer__TransferFailed);\\n        }\\n    }\\n\\n    /// @dev Transfer `amount_` of ` native token to `to_`.\\n    /// Minimally modified from Solmate SafeTransferLib (Custom Error):\\n    /// https://github.com/transmissions11/solmate/blob/50e15bb566f98b7174da9b0066126a4c3e75e0fd/src/utils/SafeTransferLib.sol#L15-L25\\n    function safeTransferNative(address to_, uint256 amount_) internal {\\n        bool success_;\\n\\n        /// @solidity memory-safe-assembly\\n        assembly {\\n            // Transfer the ETH and store if it succeeded or not.\\n            success_ := call(gas(), to_, amount_, 0, 0, 0, 0)\\n        }\\n\\n        if (!success_) {\\n            revert FluidSafeTransferError(ErrorTypes.SafeTransfer__TransferFailed);\\n        }\\n    }\\n}\\n\",\"keccak256\":\"0x7069d5801ef91035c666e05f11ccccdad310bbfc8f75b390cf44f69ff39d180d\",\"license\":\"MIT OR Apache-2.0\"},\"contracts/libraries/storageRead.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\n/// @notice implements a method to read uint256 data from storage at a bytes32 storage slot key.\\ncontract StorageRead {\\n    function readFromStorage(bytes32 slot_) public view returns (uint256 result_) {\\n        assembly {\\n            result_ := sload(slot_) // read value from the storage slot\\n        }\\n    }\\n}\\n\",\"keccak256\":\"0x1b03dfe294c2f0376f7e34c3960fe7088d7ff44bb2ffd9cb2ac940486bfba8c9\",\"license\":\"BUSL-1.1\"},\"contracts/libraries/tickMath.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\n/// @title library that calculates number \\\"tick\\\" and \\\"ratioX96\\\" from this: ratioX96 = (1.0015^tick) * 2^96\\n/// @notice this library is used in Fluid Vault protocol for optimiziation.\\n/// @dev \\\"tick\\\" supports between -32767 and 32767. \\\"ratioX96\\\" supports between 37075072 and 169307877264527972847801929085841449095838922544595\\nlibrary TickMath {\\n    /// The minimum tick that can be passed in getRatioAtTick. 1.0015**-32767\\n    int24 internal constant MIN_TICK = -32767;\\n    /// The maximum tick that can be passed in getRatioAtTick. 1.0015**32767\\n    int24 internal constant MAX_TICK = 32767;\\n\\n    uint256 internal constant FACTOR00 = 0x100000000000000000000000000000000;\\n    uint256 internal constant FACTOR01 = 0xff9dd7de423466c20352b1246ce4856f; // 2^128/1.0015**1 = 339772707859149738855091969477551883631\\n    uint256 internal constant FACTOR02 = 0xff3bd55f4488ad277531fa1c725a66d0; // 2^128/1.0015**2 = 339263812140938331358054887146831636176\\n    uint256 internal constant FACTOR03 = 0xfe78410fd6498b73cb96a6917f853259; // 2^128/1.0015**4 = 338248306163758188337119769319392490073\\n    uint256 internal constant FACTOR04 = 0xfcf2d9987c9be178ad5bfeffaa123273; // 2^128/1.0015**8 = 336226404141693512316971918999264834163\\n    uint256 internal constant FACTOR05 = 0xf9ef02c4529258b057769680fc6601b3; // 2^128/1.0015**16 = 332218786018727629051611634067491389875\\n    uint256 internal constant FACTOR06 = 0xf402d288133a85a17784a411f7aba082; // 2^128/1.0015**32 = 324346285652234375371948336458280706178\\n    uint256 internal constant FACTOR07 = 0xe895615b5beb6386553757b0352bda90; // 2^128/1.0015**64 = 309156521885964218294057947947195947664\\n    uint256 internal constant FACTOR08 = 0xd34f17a00ffa00a8309940a15930391a; // 2^128/1.0015**128 = 280877777739312896540849703637713172762 \\n    uint256 internal constant FACTOR09 = 0xae6b7961714e20548d88ea5123f9a0ff; // 2^128/1.0015**256 = 231843708922198649176471782639349113087\\n    uint256 internal constant FACTOR10 = 0x76d6461f27082d74e0feed3b388c0ca1; // 2^128/1.0015**512 = 157961477267171621126394973980180876449\\n    uint256 internal constant FACTOR11 = 0x372a3bfe0745d8b6b19d985d9a8b85bb; // 2^128/1.0015**1024 = 73326833024599564193373530205717235131\\n    uint256 internal constant FACTOR12 = 0x0be32cbee48979763cf7247dd7bb539d; // 2^128/1.0015**2048 = 15801066890623697521348224657638773661\\n    uint256 internal constant FACTOR13 = 0x8d4f70c9ff4924dac37612d1e2921e;   // 2^128/1.0015**4096 = 733725103481409245883800626999235102\\n    uint256 internal constant FACTOR14 = 0x4e009ae5519380809a02ca7aec77;     // 2^128/1.0015**8192 = 1582075887005588088019997442108535\\n    uint256 internal constant FACTOR15 = 0x17c45e641b6e95dee056ff10;         // 2^128/1.0015**16384 = 7355550435635883087458926352\\n\\n    /// The minimum value that can be returned from getRatioAtTick. Equivalent to getRatioAtTick(MIN_TICK). ~ Equivalent to `(1 << 96) * (1.0015**-32767)`\\n    uint256 internal constant MIN_RATIOX96 = 37075072;\\n    /// The maximum value that can be returned from getRatioAtTick. Equivalent to getRatioAtTick(MAX_TICK).\\n    /// ~ Equivalent to `(1 << 96) * (1.0015**32767)`, rounding etc. leading to minor difference\\n    uint256 internal constant MAX_RATIOX96 = 169307877264527972847801929085841449095838922544595;\\n\\n    uint256 internal constant ZERO_TICK_SCALED_RATIO = 0x1000000000000000000000000; // 1 << 96 // 79228162514264337593543950336\\n    uint256 internal constant _1E26 = 1e26;\\n\\n    /// @notice ratioX96 = (1.0015^tick) * 2^96\\n    /// @dev Throws if |tick| > max tick\\n    /// @param tick The input tick for the above formula\\n    /// @return ratioX96 ratio = (debt amount/collateral amount)\\n    function getRatioAtTick(int tick) internal pure returns (uint256 ratioX96) {\\n        assembly {\\n            let absTick_ := sub(xor(tick, sar(255, tick)), sar(255, tick))\\n\\n            if gt(absTick_, MAX_TICK) {\\n                revert(0, 0)\\n            }\\n            let factor_ := FACTOR00\\n            if and(absTick_, 0x1) {\\n                factor_ := FACTOR01\\n            }\\n            if and(absTick_, 0x2) {\\n                factor_ := shr(128, mul(factor_, FACTOR02))\\n            }\\n            if and(absTick_, 0x4) {\\n                factor_ := shr(128, mul(factor_, FACTOR03))\\n            }\\n            if and(absTick_, 0x8) {\\n                factor_ := shr(128, mul(factor_, FACTOR04))\\n            }\\n            if and(absTick_, 0x10) {\\n                factor_ := shr(128, mul(factor_, FACTOR05))\\n            }\\n            if and(absTick_, 0x20) {\\n                factor_ := shr(128, mul(factor_, FACTOR06))\\n            }\\n            if and(absTick_, 0x40) {\\n                factor_ := shr(128, mul(factor_, FACTOR07))\\n            }\\n            if and(absTick_, 0x80) {\\n                factor_ := shr(128, mul(factor_, FACTOR08))\\n            }\\n            if and(absTick_, 0x100) {\\n                factor_ := shr(128, mul(factor_, FACTOR09))\\n            }\\n            if and(absTick_, 0x200) {\\n                factor_ := shr(128, mul(factor_, FACTOR10))\\n            }\\n            if and(absTick_, 0x400) {\\n                factor_ := shr(128, mul(factor_, FACTOR11))\\n            }\\n            if and(absTick_, 0x800) {\\n                factor_ := shr(128, mul(factor_, FACTOR12))\\n            }\\n            if and(absTick_, 0x1000) {\\n                factor_ := shr(128, mul(factor_, FACTOR13))\\n            }\\n            if and(absTick_, 0x2000) {\\n                factor_ := shr(128, mul(factor_, FACTOR14))\\n            }\\n            if and(absTick_, 0x4000) {\\n                factor_ := shr(128, mul(factor_, FACTOR15))\\n            }\\n\\n            let precision_ := 0\\n            if iszero(and(tick, 0x8000000000000000000000000000000000000000000000000000000000000000)) {\\n                factor_ := div(0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff, factor_)\\n                // we round up in the division so getTickAtRatio of the output price is always consistent\\n                if mod(factor_, 0x100000000) {\\n                    precision_ := 1\\n                }\\n            }\\n            ratioX96 := add(shr(32, factor_), precision_)\\n        }\\n    }\\n\\n    /// @notice ratioX96 = (1.0015^tick) * 2^96\\n    /// @dev Throws if ratioX96 > max ratio || ratioX96 < min ratio\\n    /// @param ratioX96 The input ratio; ratio = (debt amount/collateral amount)\\n    /// @return tick The output tick for the above formula. Returns in round down form. if tick is 123.23 then 123, if tick is -123.23 then returns -124\\n    /// @return perfectRatioX96 perfect ratio for the above tick\\n    function getTickAtRatio(uint256 ratioX96) internal pure returns (int tick, uint perfectRatioX96) {\\n        assembly {\\n            if or(gt(ratioX96, MAX_RATIOX96), lt(ratioX96, MIN_RATIOX96)) {\\n                revert(0, 0)\\n            }\\n\\n            let cond := lt(ratioX96, ZERO_TICK_SCALED_RATIO)\\n            let factor_\\n\\n            if iszero(cond) {\\n                // if ratioX96 >= ZERO_TICK_SCALED_RATIO\\n                factor_ := div(mul(ratioX96, _1E26), ZERO_TICK_SCALED_RATIO)\\n            }\\n            if cond {\\n                // ratioX96 < ZERO_TICK_SCALED_RATIO\\n                factor_ := div(mul(ZERO_TICK_SCALED_RATIO, _1E26), ratioX96)\\n            }\\n\\n            // put in https://www.wolframalpha.com/ whole equation: (1.0015^tick) * 2^96 * 10^26 / 79228162514264337593543950336\\n\\n            // for tick = 16384\\n            // ratioX96 = (1.0015^16384) * 2^96 = 3665252098134783297721995888537077351735\\n            // 3665252098134783297721995888537077351735 * 10^26 / 79228162514264337593543950336 =\\n            // 4626198540796508716348404308345255985.06131964639489434655721\\n            if iszero(lt(factor_, 4626198540796508716348404308345255985)) {\\n                tick := or(tick, 0x4000)\\n                factor_ := div(mul(factor_, _1E26), 4626198540796508716348404308345255985)\\n            }\\n            // for tick = 8192\\n            // ratioX96 = (1.0015^8192) * 2^96 = 17040868196391020479062776466509865\\n            // 17040868196391020479062776466509865 * 10^26 / 79228162514264337593543950336 =\\n            // 21508599537851153911767490449162.3037648642153898377655505172\\n            if iszero(lt(factor_, 21508599537851153911767490449162)) {\\n                tick := or(tick, 0x2000)\\n                factor_ := div(mul(factor_, _1E26), 21508599537851153911767490449162)\\n            }\\n            // for tick = 4096\\n            // ratioX96 = (1.0015^4096) * 2^96 = 36743933851015821532611831851150\\n            // 36743933851015821532611831851150 * 10^26 / 79228162514264337593543950336 =\\n            // 46377364670549310883002866648.9777607649742626173648716941385\\n            if iszero(lt(factor_, 46377364670549310883002866649)) {\\n                tick := or(tick, 0x1000)\\n                factor_ := div(mul(factor_, _1E26), 46377364670549310883002866649)\\n            }\\n            // for tick = 2048\\n            // ratioX96 = (1.0015^2048) * 2^96 = 1706210527034005899209104452335\\n            // 1706210527034005899209104452335 * 10^26 / 79228162514264337593543950336 =\\n            // 2153540449365864845468344760.06357108484096046743300420319322\\n            if iszero(lt(factor_, 2153540449365864845468344760)) {\\n                tick := or(tick, 0x800)\\n                factor_ := div(mul(factor_, _1E26), 2153540449365864845468344760)\\n            }\\n            // for tick = 1024\\n            // ratioX96 = (1.0015^1024) * 2^96 = 367668226692760093024536487236\\n            // 367668226692760093024536487236 * 10^26 / 79228162514264337593543950336 =\\n            // 464062544207767844008185024.950588990554136265212906454481127\\n            if iszero(lt(factor_, 464062544207767844008185025)) {\\n                tick := or(tick, 0x400)\\n                factor_ := div(mul(factor_, _1E26), 464062544207767844008185025)\\n            }\\n            // for tick = 512\\n            // ratioX96 = (1.0015^512) * 2^96 = 170674186729409605620119663668\\n            // 170674186729409605620119663668 * 10^26 / 79228162514264337593543950336 =\\n            // 215421109505955298802281577.031879604792139232258508172947569\\n            if iszero(lt(factor_, 215421109505955298802281577)) {\\n                tick := or(tick, 0x200)\\n                factor_ := div(mul(factor_, _1E26), 215421109505955298802281577)\\n            }\\n            // for tick = 256\\n            // ratioX96 = (1.0015^256) * 2^96 = 116285004205991934861656513301\\n            // 116285004205991934861656513301 * 10^26 / 79228162514264337593543950336 =\\n            // 146772309890508740607270614.667650899656438875541505058062410\\n            if iszero(lt(factor_, 146772309890508740607270615)) {\\n                tick := or(tick, 0x100)\\n                factor_ := div(mul(factor_, _1E26), 146772309890508740607270615)\\n            }\\n            // for tick = 128\\n            // ratioX96 = (1.0015^128) * 2^96 = 95984619659632141743747099590\\n            // 95984619659632141743747099590 * 10^26 / 79228162514264337593543950336 =\\n            // 121149622323187099817270416.157248837742741760456796835775887\\n            if iszero(lt(factor_, 121149622323187099817270416)) {\\n                tick := or(tick, 0x80)\\n                factor_ := div(mul(factor_, _1E26), 121149622323187099817270416)\\n            }\\n            // for tick = 64\\n            // ratioX96 = (1.0015^64) * 2^96 = 87204845308406958006717891124\\n            // 87204845308406958006717891124 * 10^26 / 79228162514264337593543950336 =\\n            // 110067989135437147685980801.568068573422377364214113968609839\\n            if iszero(lt(factor_, 110067989135437147685980801)) {\\n                tick := or(tick, 0x40)\\n                factor_ := div(mul(factor_, _1E26), 110067989135437147685980801)\\n            }\\n            // for tick = 32\\n            // ratioX96 = (1.0015^32) * 2^96 = 83120873769022354029916374475\\n            // 83120873769022354029916374475 * 10^26 / 79228162514264337593543950336 =\\n            // 104913292358707887270979599.831816586773651266562785765558183\\n            if iszero(lt(factor_, 104913292358707887270979600)) {\\n                tick := or(tick, 0x20)\\n                factor_ := div(mul(factor_, _1E26), 104913292358707887270979600)\\n            }\\n            // for tick = 16\\n            // ratioX96 = (1.0015^16) * 2^96 = 81151180492336368327184716176\\n            // 81151180492336368327184716176 * 10^26 / 79228162514264337593543950336 =\\n            // 102427189924701091191840927.762844039579442328381455567932128\\n            if iszero(lt(factor_, 102427189924701091191840928)) {\\n                tick := or(tick, 0x10)\\n                factor_ := div(mul(factor_, _1E26), 102427189924701091191840928)\\n            }\\n            // for tick = 8\\n            // ratioX96 = (1.0015^8) * 2^96 = 80183906840906820640659903620\\n            // 80183906840906820640659903620 * 10^26 / 79228162514264337593543950336 =\\n            // 101206318935480056907421312.890625\\n            if iszero(lt(factor_, 101206318935480056907421313)) {\\n                tick := or(tick, 0x8)\\n                factor_ := div(mul(factor_, _1E26), 101206318935480056907421313)\\n            }\\n            // for tick = 4\\n            // ratioX96 = (1.0015^4) * 2^96 = 79704602139525152702959747603\\n            // 79704602139525152702959747603 * 10^26 / 79228162514264337593543950336 =\\n            // 100601351350506250000000000\\n            if iszero(lt(factor_, 100601351350506250000000000)) {\\n                tick := or(tick, 0x4)\\n                factor_ := div(mul(factor_, _1E26), 100601351350506250000000000)\\n            }\\n            // for tick = 2\\n            // ratioX96 = (1.0015^2) * 2^96 = 79466025265172787701084167660\\n            // 79466025265172787701084167660 * 10^26 / 79228162514264337593543950336 =\\n            // 100300225000000000000000000\\n            if iszero(lt(factor_, 100300225000000000000000000)) {\\n                tick := or(tick, 0x2)\\n                factor_ := div(mul(factor_, _1E26), 100300225000000000000000000)\\n            }\\n            // for tick = 1\\n            // ratioX96 = (1.0015^1) * 2^96 = 79347004758035734099934266261\\n            // 79347004758035734099934266261 * 10^26 / 79228162514264337593543950336 =\\n            // 100150000000000000000000000\\n            if iszero(lt(factor_, 100150000000000000000000000)) {\\n                tick := or(tick, 0x1)\\n                factor_ := div(mul(factor_, _1E26), 100150000000000000000000000)\\n            }\\n            if iszero(cond) {\\n                // if ratioX96 >= ZERO_TICK_SCALED_RATIO\\n                perfectRatioX96 := div(mul(ratioX96, _1E26), factor_)\\n            }\\n            if cond {\\n                // ratioX96 < ZERO_TICK_SCALED_RATIO\\n                tick := not(tick)\\n                perfectRatioX96 := div(mul(ratioX96, factor_), 100150000000000000000000000)\\n            }\\n        }\\n    }\\n}\\n\",\"keccak256\":\"0x80473c7b515295e6570cae8c0322202512ef2073d82c560d0bafc1bf896dd83c\",\"license\":\"BUSL-1.1\"},\"contracts/liquidity/adminModule/structs.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nabstract contract Structs {\\n    struct AddressBool {\\n        address addr;\\n        bool value;\\n    }\\n\\n    struct AddressUint256 {\\n        address addr;\\n        uint256 value;\\n    }\\n\\n    /// @notice struct to set borrow rate data for version 1\\n    struct RateDataV1Params {\\n        ///\\n        /// @param token for rate data\\n        address token;\\n        ///\\n        /// @param kink in borrow rate. in 1e2: 100% = 10_000; 1% = 100\\n        /// utilization below kink usually means slow increase in rate, once utilization is above kink borrow rate increases fast\\n        uint256 kink;\\n        ///\\n        /// @param rateAtUtilizationZero desired borrow rate when utilization is zero. in 1e2: 100% = 10_000; 1% = 100\\n        /// i.e. constant minimum borrow rate\\n        /// e.g. at utilization = 0.01% rate could still be at least 4% (rateAtUtilizationZero would be 400 then)\\n        uint256 rateAtUtilizationZero;\\n        ///\\n        /// @param rateAtUtilizationKink borrow rate when utilization is at kink. in 1e2: 100% = 10_000; 1% = 100\\n        /// e.g. when rate should be 7% at kink then rateAtUtilizationKink would be 700\\n        uint256 rateAtUtilizationKink;\\n        ///\\n        /// @param rateAtUtilizationMax borrow rate when utilization is maximum at 100%. in 1e2: 100% = 10_000; 1% = 100\\n        /// e.g. when rate should be 125% at 100% then rateAtUtilizationMax would be 12_500\\n        uint256 rateAtUtilizationMax;\\n    }\\n\\n    /// @notice struct to set borrow rate data for version 2\\n    struct RateDataV2Params {\\n        ///\\n        /// @param token for rate data\\n        address token;\\n        ///\\n        /// @param kink1 first kink in borrow rate. in 1e2: 100% = 10_000; 1% = 100\\n        /// utilization below kink 1 usually means slow increase in rate, once utilization is above kink 1 borrow rate increases faster\\n        uint256 kink1;\\n        ///\\n        /// @param kink2 second kink in borrow rate. in 1e2: 100% = 10_000; 1% = 100\\n        /// utilization below kink 2 usually means slow / medium increase in rate, once utilization is above kink 2 borrow rate increases fast\\n        uint256 kink2;\\n        ///\\n        /// @param rateAtUtilizationZero desired borrow rate when utilization is zero. in 1e2: 100% = 10_000; 1% = 100\\n        /// i.e. constant minimum borrow rate\\n        /// e.g. at utilization = 0.01% rate could still be at least 4% (rateAtUtilizationZero would be 400 then)\\n        uint256 rateAtUtilizationZero;\\n        ///\\n        /// @param rateAtUtilizationKink1 desired borrow rate when utilization is at first kink. in 1e2: 100% = 10_000; 1% = 100\\n        /// e.g. when rate should be 7% at first kink then rateAtUtilizationKink would be 700\\n        uint256 rateAtUtilizationKink1;\\n        ///\\n        /// @param rateAtUtilizationKink2 desired borrow rate when utilization is at second kink. in 1e2: 100% = 10_000; 1% = 100\\n        /// e.g. when rate should be 7% at second kink then rateAtUtilizationKink would be 1_200\\n        uint256 rateAtUtilizationKink2;\\n        ///\\n        /// @param rateAtUtilizationMax desired borrow rate when utilization is maximum at 100%. in 1e2: 100% = 10_000; 1% = 100\\n        /// e.g. when rate should be 125% at 100% then rateAtUtilizationMax would be 12_500\\n        uint256 rateAtUtilizationMax;\\n    }\\n\\n    /// @notice struct to set token config\\n    struct TokenConfig {\\n        ///\\n        /// @param token address\\n        address token;\\n        ///\\n        /// @param fee charges on borrower's interest. in 1e2: 100% = 10_000; 1% = 100\\n        uint256 fee;\\n        ///\\n        /// @param threshold on when to update the storage slot. in 1e2: 100% = 10_000; 1% = 100\\n        uint256 threshold;\\n    }\\n\\n    /// @notice struct to set user supply & withdrawal config\\n    struct UserSupplyConfig {\\n        ///\\n        /// @param user address\\n        address user;\\n        ///\\n        /// @param token address\\n        address token;\\n        ///\\n        /// @param mode: 0 = without interest. 1 = with interest\\n        uint8 mode;\\n        ///\\n        /// @param expandPercent withdrawal limit expand percent. in 1e2: 100% = 10_000; 1% = 100\\n        /// Also used to calculate rate at which withdrawal limit should decrease (instant).\\n        uint256 expandPercent;\\n        ///\\n        /// @param expandDuration withdrawal limit expand duration in seconds.\\n        /// used to calculate rate together with expandPercent\\n        uint256 expandDuration;\\n        ///\\n        /// @param baseWithdrawalLimit base limit, below this, user can withdraw the entire amount.\\n        /// amount in raw (to be multiplied with exchange price) or normal depends on configured mode in user config for the token:\\n        /// with interest -> raw, without interest -> normal\\n        uint256 baseWithdrawalLimit;\\n    }\\n\\n    /// @notice struct to set user borrow & payback config\\n    struct UserBorrowConfig {\\n        ///\\n        /// @param user address\\n        address user;\\n        ///\\n        /// @param token address\\n        address token;\\n        ///\\n        /// @param mode: 0 = without interest. 1 = with interest\\n        uint8 mode;\\n        ///\\n        /// @param expandPercent debt limit expand percent. in 1e2: 100% = 10_000; 1% = 100\\n        /// Also used to calculate rate at which debt limit should decrease (instant).\\n        uint256 expandPercent;\\n        ///\\n        /// @param expandDuration debt limit expand duration in seconds.\\n        /// used to calculate rate together with expandPercent\\n        uint256 expandDuration;\\n        ///\\n        /// @param baseDebtCeiling base borrow limit. until here, borrow limit remains as baseDebtCeiling\\n        /// (user can borrow until this point at once without stepped expansion). Above this, automated limit comes in place.\\n        /// amount in raw (to be multiplied with exchange price) or normal depends on configured mode in user config for the token:\\n        /// with interest -> raw, without interest -> normal\\n        uint256 baseDebtCeiling;\\n        ///\\n        /// @param maxDebtCeiling max borrow ceiling, maximum amount the user can borrow.\\n        /// amount in raw (to be multiplied with exchange price) or normal depends on configured mode in user config for the token:\\n        /// with interest -> raw, without interest -> normal\\n        uint256 maxDebtCeiling;\\n    }\\n}\\n\",\"keccak256\":\"0xcacc14afd7880d3179d0089d65dad6714c377df4801a9ad79a499d0d079124c0\",\"license\":\"BUSL-1.1\"},\"contracts/liquidity/interfaces/iLiquidity.sol\":{\"content\":\"//SPDX-License-Identifier: MIT\\npragma solidity 0.8.21;\\n\\nimport { IProxy } from \\\"../../infiniteProxy/interfaces/iProxy.sol\\\";\\nimport { Structs as AdminModuleStructs } from \\\"../adminModule/structs.sol\\\";\\n\\ninterface IFluidLiquidityAdmin {\\n    /// @notice adds/removes auths. Auths generally could be contracts which can have restricted actions defined on contract.\\n    ///         auths can be helpful in reducing governance overhead where it's not needed.\\n    /// @param authsStatus_ array of structs setting allowed status for an address.\\n    ///                     status true => add auth, false => remove auth\\n    function updateAuths(AdminModuleStructs.AddressBool[] calldata authsStatus_) external;\\n\\n    /// @notice adds/removes guardians. Only callable by Governance.\\n    /// @param guardiansStatus_ array of structs setting allowed status for an address.\\n    ///                         status true => add guardian, false => remove guardian\\n    function updateGuardians(AdminModuleStructs.AddressBool[] calldata guardiansStatus_) external;\\n\\n    /// @notice changes the revenue collector address (contract that is sent revenue). Only callable by Governance.\\n    /// @param revenueCollector_  new revenue collector address\\n    function updateRevenueCollector(address revenueCollector_) external;\\n\\n    /// @notice changes current status, e.g. for pausing or unpausing all user operations. Only callable by Auths.\\n    /// @param newStatus_ new status\\n    ///        status = 2 -> pause, status = 1 -> resume.\\n    function changeStatus(uint256 newStatus_) external;\\n\\n    /// @notice                  update tokens rate data version 1. Only callable by Auths.\\n    /// @param tokensRateData_   array of RateDataV1Params with rate data to set for each token\\n    function updateRateDataV1s(AdminModuleStructs.RateDataV1Params[] calldata tokensRateData_) external;\\n\\n    /// @notice                  update tokens rate data version 2. Only callable by Auths.\\n    /// @param tokensRateData_   array of RateDataV2Params with rate data to set for each token\\n    function updateRateDataV2s(AdminModuleStructs.RateDataV2Params[] calldata tokensRateData_) external;\\n\\n    /// @notice updates token configs: fee charge on borrowers interest & storage update utilization threshold.\\n    ///         Only callable by Auths.\\n    /// @param tokenConfigs_ contains token address, fee & utilization threshold\\n    function updateTokenConfigs(AdminModuleStructs.TokenConfig[] calldata tokenConfigs_) external;\\n\\n    /// @notice updates user classes: 0 is for new protocols, 1 is for established protocols.\\n    ///         Only callable by Auths.\\n    /// @param userClasses_ struct array of uint256 value to assign for each user address\\n    function updateUserClasses(AdminModuleStructs.AddressUint256[] calldata userClasses_) external;\\n\\n    /// @notice sets user supply configs per token basis. Eg: with interest or interest-free and automated limits.\\n    ///         Only callable by Auths.\\n    /// @param userSupplyConfigs_ struct array containing user supply config, see `UserSupplyConfig` struct for more info\\n    function updateUserSupplyConfigs(AdminModuleStructs.UserSupplyConfig[] memory userSupplyConfigs_) external;\\n\\n    /// @notice setting user borrow configs per token basis. Eg: with interest or interest-free and automated limits.\\n    ///         Only callable by Auths.\\n    /// @param userBorrowConfigs_ struct array containing user borrow config, see `UserBorrowConfig` struct for more info\\n    function updateUserBorrowConfigs(AdminModuleStructs.UserBorrowConfig[] memory userBorrowConfigs_) external;\\n\\n    /// @notice pause operations for a particular user in class 0 (class 1 users can't be paused by guardians).\\n    /// Only callable by Guardians.\\n    /// @param user_          address of user to pause operations for\\n    /// @param supplyTokens_  token addresses to pause withdrawals for\\n    /// @param borrowTokens_  token addresses to pause borrowings for\\n    function pauseUser(address user_, address[] calldata supplyTokens_, address[] calldata borrowTokens_) external;\\n\\n    /// @notice unpause operations for a particular user in class 0 (class 1 users can't be paused by guardians).\\n    /// Only callable by Guardians.\\n    /// @param user_          address of user to unpause operations for\\n    /// @param supplyTokens_  token addresses to unpause withdrawals for\\n    /// @param borrowTokens_  token addresses to unpause borrowings for\\n    function unpauseUser(address user_, address[] calldata supplyTokens_, address[] calldata borrowTokens_) external;\\n\\n    /// @notice         collects revenue for tokens to configured revenueCollector address.\\n    /// @param tokens_  array of tokens to collect revenue for\\n    /// @dev            Note that this can revert if token balance is < revenueAmount (utilization > 100%)\\n    function collectRevenue(address[] calldata tokens_) external;\\n\\n    /// @notice gets the current updated exchange prices for n tokens and updates all prices, rates related data in storage.\\n    /// @param tokens_ tokens to update exchange prices for\\n    /// @return supplyExchangePrices_ new supply rates of overall system for each token\\n    /// @return borrowExchangePrices_ new borrow rates of overall system for each token\\n    function updateExchangePrices(\\n        address[] calldata tokens_\\n    ) external returns (uint256[] memory supplyExchangePrices_, uint256[] memory borrowExchangePrices_);\\n}\\n\\ninterface IFluidLiquidityLogic is IFluidLiquidityAdmin {\\n    /// @notice Single function which handles supply, withdraw, borrow & payback\\n    /// @param token_ address of token (0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE for native)\\n    /// @param supplyAmount_ if +ve then supply, if -ve then withdraw, if 0 then nothing\\n    /// @param borrowAmount_ if +ve then borrow, if -ve then payback, if 0 then nothing\\n    /// @param withdrawTo_ if withdrawal then to which address\\n    /// @param borrowTo_ if borrow then to which address\\n    /// @param callbackData_ callback data passed to `liquidityCallback` method of protocol\\n    /// @return memVar3_ updated supplyExchangePrice\\n    /// @return memVar4_ updated borrowExchangePrice\\n    /// @dev to trigger skipping in / out transfers when in&out amounts balance themselves out (gas optimization):\\n    /// -   supply(+) == borrow(+), withdraw(-) == payback(-).\\n    /// -   `withdrawTo_` / `borrowTo_` must be msg.sender (protocol)\\n    /// -   `callbackData_` MUST be encoded so that \\\"from\\\" address is at last 20 bytes (if this optimization is desired),\\n    ///     also for native token operations where liquidityCallback is not triggered!\\n    ///     from address must come at last position if there is more data. I.e. encode like:\\n    ///     abi.encode(otherVar1, otherVar2, FROM_ADDRESS). Note dynamic types used with abi.encode come at the end\\n    ///     so if dynamic types are needed, you must use abi.encodePacked to ensure the from address is at the end.\\n    function operate(\\n        address token_,\\n        int256 supplyAmount_,\\n        int256 borrowAmount_,\\n        address withdrawTo_,\\n        address borrowTo_,\\n        bytes calldata callbackData_\\n    ) external payable returns (uint256 memVar3_, uint256 memVar4_);\\n}\\n\\ninterface IFluidLiquidity is IProxy, IFluidLiquidityLogic {}\\n\",\"keccak256\":\"0xc81ac0cfc8183ec57ec4e488b07a4f6d1ecd79787e0aaf0dcfdd0b9b7ac0fc84\",\"license\":\"MIT\"},\"contracts/oracle/fluidOracle.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nimport { IFluidOracle } from \\\"./interfaces/iFluidOracle.sol\\\";\\n\\n/// @title   FluidOracle\\n/// @notice  Base contract that any Fluid Oracle must implement\\nabstract contract FluidOracle is IFluidOracle {\\n    /// @inheritdoc IFluidOracle\\n    function getExchangeRate() external view virtual returns (uint256 exchangeRate_);\\n}\\n\",\"keccak256\":\"0xdb26c5b753d614b855566682b0bb2ae14ef26d25b7b2cb3c5ba7fe79c42c079b\",\"license\":\"BUSL-1.1\"},\"contracts/oracle/interfaces/iFluidOracle.sol\":{\"content\":\"// SPDX-License-Identifier: MIT\\npragma solidity 0.8.21;\\n\\ninterface IFluidOracle {\\n    /// @notice Get the `exchangeRate_` between the underlying asset and the peg asset in 1e27\\n    function getExchangeRate() external view returns (uint256 exchangeRate_);\\n}\\n\",\"keccak256\":\"0xcbdd2f8aa2dc30ef9865e9d8505705254fd106ecd239c59b39bdbf6801526497\",\"license\":\"MIT\"},\"contracts/protocols/vault/error.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\ncontract Error {\\n    error FluidVaultError(uint256 errorId_);\\n\\n    /// @notice used to simulate liquidation to find the maximum liquidatable amounts\\n    error FluidLiquidateResult(uint256 colLiquidated, uint256 debtLiquidated);\\n}\\n\",\"keccak256\":\"0x84d885c40fdca6828cb4cdc206c852fc4ad7e52f7621e2a63b151742123196f5\",\"license\":\"BUSL-1.1\"},\"contracts/protocols/vault/errorTypes.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nlibrary ErrorTypes {\\n    /***********************************|\\n    |           Vault Factory           | \\n    |__________________________________*/\\n\\n    uint256 internal constant VaultFactory__InvalidOperation = 30001;\\n    uint256 internal constant VaultFactory__Unauthorized = 30002;\\n    uint256 internal constant VaultFactory__SameTokenNotAllowed = 30003;\\n    uint256 internal constant VaultFactory__InvalidParams = 30004;\\n    uint256 internal constant VaultFactory__InvalidVault = 30005;\\n    uint256 internal constant VaultFactory__InvalidVaultAddress = 30006;\\n    uint256 internal constant VaultFactory__OnlyDelegateCallAllowed = 30007;\\n\\n    /***********************************|\\n    |            VaultT1                | \\n    |__________________________________*/\\n\\n    /// @notice thrown at reentrancy\\n    uint256 internal constant VaultT1__AlreadyEntered = 31001;\\n\\n    /// @notice thrown when user sends deposit & borrow amount as 0\\n    uint256 internal constant VaultT1__InvalidOperateAmount = 31002;\\n\\n    /// @notice thrown when msg.value is not in sync with native token deposit or payback\\n    uint256 internal constant VaultT1__InvalidMsgValueOperate = 31003;\\n\\n    /// @notice thrown when msg.sender is not the owner of the vault\\n    uint256 internal constant VaultT1__NotAnOwner = 31004;\\n\\n    /// @notice thrown when user's position does not exist. Sending the wrong index from the frontend\\n    uint256 internal constant VaultT1__TickIsEmpty = 31005;\\n\\n    /// @notice thrown when the user's position is above CF and the user tries to make it more risky by trying to withdraw or borrow\\n    uint256 internal constant VaultT1__PositionAboveCF = 31006;\\n\\n    /// @notice thrown when the top tick is not initialized. Happens if the vault is totally new or all the user's left\\n    uint256 internal constant VaultT1__TopTickDoesNotExist = 31007;\\n\\n    /// @notice thrown when msg.value in liquidate is not in sync payback\\n    uint256 internal constant VaultT1__InvalidMsgValueLiquidate = 31008;\\n\\n    /// @notice thrown when slippage is more on liquidation than what the liquidator sent\\n    uint256 internal constant VaultT1__ExcessSlippageLiquidation = 31009;\\n\\n    /// @notice thrown when msg.sender is not the rebalancer/reserve contract\\n    uint256 internal constant VaultT1__NotRebalancer = 31010;\\n\\n    /// @notice thrown when NFT of one vault interacts with the NFT of other vault\\n    uint256 internal constant VaultT1__NftNotOfThisVault = 31011;\\n\\n    /// @notice thrown when the token is not initialized on the liquidity contract\\n    uint256 internal constant VaultT1__TokenNotInitialized = 31012;\\n\\n    /// @notice thrown when admin updates fallback if a non-auth calls vault\\n    uint256 internal constant VaultT1__NotAnAuth = 31013;\\n\\n    /// @notice thrown in operate when user tries to witdhraw more collateral than deposited\\n    uint256 internal constant VaultT1__ExcessCollateralWithdrawal = 31014;\\n\\n    /// @notice thrown in operate when user tries to payback more debt than borrowed\\n    uint256 internal constant VaultT1__ExcessDebtPayback = 31015;\\n\\n    /// @notice thrown when user try to withdrawal more than operate's withdrawal limit\\n    uint256 internal constant VaultT1__WithdrawMoreThanOperateLimit = 31016;\\n\\n    /// @notice thrown when caller of liquidityCallback is not Liquidity\\n    uint256 internal constant VaultT1__InvalidLiquidityCallbackAddress = 31017;\\n\\n    /// @notice thrown when reentrancy is not already on\\n    uint256 internal constant VaultT1__NotEntered = 31018;\\n\\n    /// @notice thrown when someone directly calls secondary implementation contract\\n    uint256 internal constant VaultT1__OnlyDelegateCallAllowed = 31019;\\n\\n    /// @notice thrown when the safeTransferFrom for a token amount failed\\n    uint256 internal constant VaultT1__TransferFromFailed = 31020;\\n\\n    /// @notice thrown when exchange price overflows while updating on storage\\n    uint256 internal constant VaultT1__ExchangePriceOverFlow = 31021;\\n\\n    /// @notice thrown when debt to liquidate amt is sent wrong\\n    uint256 internal constant VaultT1__InvalidLiquidationAmt = 31022;\\n\\n    /// @notice thrown when user debt or collateral goes above 2**128 or below -2**128\\n    uint256 internal constant VaultT1__UserCollateralDebtExceed = 31023;\\n\\n    /// @notice thrown if on liquidation branch debt becomes lower than 100\\n    uint256 internal constant VaultT1__BranchDebtTooLow = 31024;\\n\\n    /// @notice thrown when tick's debt is less than 10000\\n    uint256 internal constant VaultT1__TickDebtTooLow = 31025;\\n\\n    /// @notice thrown when the received new liquidity exchange price is of unexpected value (< than the old one)\\n    uint256 internal constant VaultT1__LiquidityExchangePriceUnexpected = 31026;\\n\\n    /// @notice thrown when user's debt is less than 10000\\n    uint256 internal constant VaultT1__UserDebtTooLow = 31027;\\n\\n    /// @notice thrown when on only payback and only deposit the ratio of position increases\\n    uint256 internal constant VaultT1__InvalidPaybackOrDeposit = 31028;\\n\\n    /// @notice thrown when liquidation just happens of a single partial\\n    uint256 internal constant VaultT1__InvalidLiquidation = 31029;\\n\\n    /***********************************|\\n    |              ERC721               | \\n    |__________________________________*/\\n\\n    uint256 internal constant ERC721__InvalidParams = 32001;\\n    uint256 internal constant ERC721__Unauthorized = 32002;\\n    uint256 internal constant ERC721__InvalidOperation = 32003;\\n    uint256 internal constant ERC721__UnsafeRecipient = 32004;\\n    uint256 internal constant ERC721__OutOfBoundsIndex = 32005;\\n\\n    /***********************************|\\n    |            Vault Admin            | \\n    |__________________________________*/\\n\\n    /// @notice thrown when admin tries to setup invalid value which are crossing limits\\n    uint256 internal constant VaultT1Admin__ValueAboveLimit = 33001;\\n\\n    /// @notice when someone directly calls admin implementation contract\\n    uint256 internal constant VaultT1Admin__OnlyDelegateCallAllowed = 33002;\\n\\n    /// @notice thrown when auth sends NFT ID as 0 while collecting dust debt\\n    uint256 internal constant VaultT1Admin__NftIdShouldBeNonZero = 33003;\\n\\n    /// @notice thrown when trying to collect dust debt of NFT which is not of this vault\\n    uint256 internal constant VaultT1Admin__NftNotOfThisVault = 33004;\\n\\n    /// @notice thrown when dust debt of NFT is 0, meaning nothing to collect\\n    uint256 internal constant VaultT1Admin__DustDebtIsZero = 33005;\\n\\n    /// @notice thrown when final debt after liquidation is not 0, meaning position 100% liquidated\\n    uint256 internal constant VaultT1Admin__FinalDebtShouldBeZero = 33006;\\n\\n    /// @notice thrown when NFT is not liquidated state\\n    uint256 internal constant VaultT1Admin__NftNotLiquidated = 33007;\\n\\n    /// @notice thrown when total absorbed dust debt is 0\\n    uint256 internal constant VaultT1Admin__AbsorbedDustDebtIsZero = 33008;\\n\\n    /// @notice thrown when address is set as 0\\n    uint256 internal constant VaultT1Admin__AddressZeroNotAllowed = 33009;\\n\\n    /***********************************|\\n    |            Vault Rewards          | \\n    |__________________________________*/\\n\\n    uint256 internal constant VaultRewards__Unauthorized = 34001;\\n    uint256 internal constant VaultRewards__AddressZero = 34002;\\n    uint256 internal constant VaultRewards__InvalidParams = 34003;\\n    uint256 internal constant VaultRewards__NewMagnifierSameAsOldMagnifier = 34004;\\n    uint256 internal constant VaultRewards__NotTheInitiator = 34005;\\n    uint256 internal constant VaultRewards__AlreadyStarted = 34006;\\n    uint256 internal constant VaultRewards__RewardsNotStartedOrEnded = 34007;\\n}\\n\",\"keccak256\":\"0x172538f0fb102995d611b7923c6ae5c8f30dcb56d525bf01234102896a95c8b0\",\"license\":\"BUSL-1.1\"},\"contracts/protocols/vault/factory/deploymentLogics/vaultT1Logic.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nimport { SSTORE2 } from \\\"solmate/src/utils/SSTORE2.sol\\\";\\n\\nimport { ErrorTypes } from \\\"../../errorTypes.sol\\\";\\nimport { Error } from \\\"../../error.sol\\\";\\nimport { IFluidVaultFactory } from \\\"../../interfaces/iVaultFactory.sol\\\";\\n\\nimport { LiquiditySlotsLink } from \\\"../../../../libraries/liquiditySlotsLink.sol\\\";\\n\\nimport { IFluidVaultT1 } from \\\"../../interfaces/iVaultT1.sol\\\";\\nimport { FluidVaultT1 } from \\\"../../vaultT1/coreModule/main.sol\\\";\\n\\ninterface IERC20 {\\n    function decimals() external view returns (uint8);\\n}\\n\\ncontract FluidVaultT1DeploymentLogic is Error {\\n    address internal constant NATIVE_TOKEN = 0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE;\\n\\n    /// @notice SSTORE2 pointer for the VaultT1 creation code. Stored externally to reduce factory bytecode\\n    address public immutable VAULT_T1_CREATIONCODE_ADDRESS;\\n\\n    /// @notice address of liquidity contract\\n    address public immutable LIQUIDITY;\\n\\n    /// @notice address of Admin implementation\\n    address public immutable ADMIN_IMPLEMENTATION;\\n\\n    /// @notice address of Secondary implementation\\n    address public immutable SECONDARY_IMPLEMENTATION;\\n\\n    /// @notice address of this contract\\n    address public immutable ADDRESS_THIS;\\n\\n    /// @notice Emitted when a new vaultT1 is deployed.\\n    /// @param vault The address of the newly deployed vault.\\n    /// @param vaultId The id of the newly deployed vault.\\n    /// @param supplyToken The address of the supply token.\\n    /// @param borrowToken The address of the borrow token.\\n    event VaultT1Deployed(\\n        address indexed vault,\\n        uint256 vaultId,\\n        address indexed supplyToken,\\n        address indexed borrowToken\\n    );\\n\\n    constructor(address liquidity_, address vaultAdminImplementation_, address vaultSecondaryImplementation_) {\\n        LIQUIDITY = liquidity_;\\n        ADMIN_IMPLEMENTATION = vaultAdminImplementation_;\\n        SECONDARY_IMPLEMENTATION = vaultSecondaryImplementation_;\\n        VAULT_T1_CREATIONCODE_ADDRESS = SSTORE2.write(type(FluidVaultT1).creationCode);\\n        ADDRESS_THIS = address(this);\\n    }\\n\\n    /// @dev                            Calculates the liquidity vault slots for the given supply token, borrow token, and vault (`vault_`).\\n    /// @param constants_               Constants struct as used in Vault T1\\n    /// @param vault_                   The address of the vault.\\n    /// @return liquidityVaultSlots_    Returns the calculated liquidity vault slots set in the `IFluidVaultT1.ConstantViews` struct.\\n    function _calculateLiquidityVaultSlots(\\n        IFluidVaultT1.ConstantViews memory constants_,\\n        address vault_\\n    ) private pure returns (IFluidVaultT1.ConstantViews memory) {\\n        constants_.liquiditySupplyExchangePriceSlot = LiquiditySlotsLink.calculateMappingStorageSlot(\\n            LiquiditySlotsLink.LIQUIDITY_EXCHANGE_PRICES_MAPPING_SLOT,\\n            constants_.supplyToken\\n        );\\n        constants_.liquidityBorrowExchangePriceSlot = LiquiditySlotsLink.calculateMappingStorageSlot(\\n            LiquiditySlotsLink.LIQUIDITY_EXCHANGE_PRICES_MAPPING_SLOT,\\n            constants_.borrowToken\\n        );\\n        constants_.liquidityUserSupplySlot = LiquiditySlotsLink.calculateDoubleMappingStorageSlot(\\n            LiquiditySlotsLink.LIQUIDITY_USER_SUPPLY_DOUBLE_MAPPING_SLOT,\\n            vault_,\\n            constants_.supplyToken\\n        );\\n        constants_.liquidityUserBorrowSlot = LiquiditySlotsLink.calculateDoubleMappingStorageSlot(\\n            LiquiditySlotsLink.LIQUIDITY_USER_BORROW_DOUBLE_MAPPING_SLOT,\\n            vault_,\\n            constants_.borrowToken\\n        );\\n        return constants_;\\n    }\\n\\n    /// @notice                         Computes vaultT1 bytecode for the given supply token (`supplyToken_`) and borrow token (`borrowToken_`).\\n    ///                                 This will be called by the VaultFactory via .delegateCall\\n    /// @param supplyToken_             The address of the supply token.\\n    /// @param borrowToken_             The address of the borrow token.\\n    /// @return vaultCreationBytecode_  Returns the bytecode of the new vault to deploy.\\n    function vaultT1(\\n        address supplyToken_,\\n        address borrowToken_\\n    ) external returns (bytes memory vaultCreationBytecode_) {\\n        if (address(this) == ADDRESS_THIS) revert FluidVaultError(ErrorTypes.VaultFactory__OnlyDelegateCallAllowed);\\n\\n        if (supplyToken_ == borrowToken_) revert FluidVaultError(ErrorTypes.VaultFactory__SameTokenNotAllowed);\\n\\n        IFluidVaultT1.ConstantViews memory constants_;\\n        constants_.liquidity = LIQUIDITY;\\n        constants_.factory = address(this);\\n        constants_.adminImplementation = ADMIN_IMPLEMENTATION;\\n        constants_.secondaryImplementation = SECONDARY_IMPLEMENTATION;\\n        constants_.supplyToken = supplyToken_;\\n        constants_.supplyDecimals = supplyToken_ != NATIVE_TOKEN ? IERC20(supplyToken_).decimals() : 18;\\n        constants_.borrowToken = borrowToken_;\\n        constants_.borrowDecimals = borrowToken_ != NATIVE_TOKEN ? IERC20(borrowToken_).decimals() : 18;\\n        constants_.vaultId = IFluidVaultFactory(address(this)).totalVaults();\\n\\n        address vault_ = IFluidVaultFactory(address(this)).getVaultAddress(constants_.vaultId);\\n\\n        constants_ = _calculateLiquidityVaultSlots(constants_, vault_);\\n\\n        vaultCreationBytecode_ = abi.encodePacked(SSTORE2.read(VAULT_T1_CREATIONCODE_ADDRESS), abi.encode(constants_));\\n\\n        emit VaultT1Deployed(vault_, constants_.vaultId, supplyToken_, borrowToken_);\\n\\n        return vaultCreationBytecode_;\\n    }\\n}\\n\",\"keccak256\":\"0x2f0c9011adadff6903f703b7744b93781a25115e4fd6c2355efc4bab2e24fd35\",\"license\":\"BUSL-1.1\"},\"contracts/protocols/vault/interfaces/iVaultFactory.sol\":{\"content\":\"//SPDX-License-Identifier: MIT\\npragma solidity 0.8.21;\\n\\nimport { IERC721Enumerable } from \\\"@openzeppelin/contracts/token/ERC721/extensions/IERC721Enumerable.sol\\\";\\n\\ninterface IFluidVaultFactory is IERC721Enumerable {\\n    /// @notice Minting an NFT Vault for the user\\n    function mint(uint256 vaultId_, address user_) external returns (uint256 tokenId_);\\n\\n    /// @notice returns owner of Vault which is also an NFT\\n    function ownerOf(uint256 tokenId) external view returns (address owner);\\n\\n    /// @notice Global auth is auth for all vaults\\n    function isGlobalAuth(address auth_) external view returns (bool);\\n\\n    /// @notice Vault auth is auth for a specific vault\\n    function isVaultAuth(address auth_, address vault_) external view returns (bool);\\n\\n    /// @notice Total vaults deployed.\\n    function totalVaults() external view returns (uint256);\\n\\n    /// @notice Compute vaultAddress\\n    function getVaultAddress(uint256 vaultId) external view returns (address);\\n\\n    /// @notice read uint256 `result_` for a storage `slot_` key\\n    function readFromStorage(bytes32 slot_) external view returns (uint256 result_);\\n}\\n\",\"keccak256\":\"0xd5c71c9e23b9d4a303f204eb3f2f4e5f1673846423f99e9e5aaa1d7020df632b\",\"license\":\"MIT\"},\"contracts/protocols/vault/interfaces/iVaultT1.sol\":{\"content\":\"//SPDX-License-Identifier: MIT\\npragma solidity 0.8.21;\\n\\ninterface IFluidVaultT1 {\\n    /// @notice returns the vault id\\n    function VAULT_ID() external view returns (uint256);\\n\\n    /// @notice reads uint256 data `result_` from storage at a bytes32 storage `slot_` key.\\n    function readFromStorage(bytes32 slot_) external view returns (uint256 result_);\\n\\n    struct ConstantViews {\\n        address liquidity;\\n        address factory;\\n        address adminImplementation;\\n        address secondaryImplementation;\\n        address supplyToken;\\n        address borrowToken;\\n        uint8 supplyDecimals;\\n        uint8 borrowDecimals;\\n        uint vaultId;\\n        bytes32 liquiditySupplyExchangePriceSlot;\\n        bytes32 liquidityBorrowExchangePriceSlot;\\n        bytes32 liquidityUserSupplySlot;\\n        bytes32 liquidityUserBorrowSlot;\\n    }\\n\\n    /// @notice returns all Vault constants\\n    function constantsView() external view returns (ConstantViews memory constantsView_);\\n\\n    /// @notice fetches the latest user position after a liquidation\\n    function fetchLatestPosition(\\n        int256 positionTick_,\\n        uint256 positionTickId_,\\n        uint256 positionRawDebt_,\\n        uint256 tickData_\\n    )\\n        external\\n        view\\n        returns (\\n            int256, // tick\\n            uint256, // raw debt\\n            uint256, // raw collateral\\n            uint256, // branchID_\\n            uint256 // branchData_\\n        );\\n\\n    /// @notice calculates the updated vault exchange prices\\n    function updateExchangePrices(\\n        uint256 vaultVariables2_\\n    )\\n        external\\n        view\\n        returns (\\n            uint256 liqSupplyExPrice_,\\n            uint256 liqBorrowExPrice_,\\n            uint256 vaultSupplyExPrice_,\\n            uint256 vaultBorrowExPrice_\\n        );\\n\\n    /// @notice calculates the updated vault exchange prices and writes them to storage\\n    function updateExchangePricesOnStorage()\\n        external\\n        returns (\\n            uint256 liqSupplyExPrice_,\\n            uint256 liqBorrowExPrice_,\\n            uint256 vaultSupplyExPrice_,\\n            uint256 vaultBorrowExPrice_\\n        );\\n\\n    /// @notice returns the liquidity contract address\\n    function LIQUIDITY() external view returns (address);\\n\\n    function operate(\\n        uint256 nftId_, // if 0 then new position\\n        int256 newCol_, // if negative then withdraw\\n        int256 newDebt_, // if negative then payback\\n        address to_ // address at which the borrow & withdraw amount should go to. If address(0) then it'll go to msg.sender\\n    )\\n        external\\n        payable\\n        returns (\\n            uint256, // nftId_\\n            int256, // final supply amount. if - then withdraw\\n            int256 // final borrow amount. if - then payback\\n        );\\n    \\n    function liquidate(\\n        uint256 debtAmt_,\\n        uint256 colPerUnitDebt_, // min collateral needed per unit of debt in 1e18\\n        address to_,\\n        bool absorb_\\n    ) external payable returns (uint actualDebtAmt_, uint actualColAmt_);\\n\\n    function absorb() external;\\n\\n    function rebalance() external payable returns (int supplyAmt_, int borrowAmt_);\\n\\n    error FluidLiquidateResult(uint256 colLiquidated, uint256 debtLiquidated);\\n}\\n\",\"keccak256\":\"0xe0ec40a4531ecbcd7b8db25b4cd8529e0c284bb20eb40b7cf909fb8af0e3ca8b\",\"license\":\"MIT\"},\"contracts/protocols/vault/vaultT1/common/variables.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\ncontract Variables {\\n    /***********************************|\\n    |         Storage Variables         |\\n    |__________________________________*/\\n\\n    /// note: in all variables. For tick >= 0 are represented with bit as 1, tick < 0 are represented with bit as 0\\n    /// note: read all the variables through storageRead.sol\\n\\n    /// note: vaultVariables contains vault variables which need regular updates through transactions\\n    /// First 1 bit => 0 => re-entrancy. If 0 then allow transaction to go, else throw.\\n    /// Next 1 bit => 1 => Is the current active branch liquidated? If true then check the branch's minima tick before creating a new position\\n    /// If the new tick is greater than minima tick then initialize a new branch, make that as current branch & do proper linking\\n    /// Next 1 bit => 2 => sign of topmost tick (0 -> negative; 1 -> positive)\\n    /// Next 19 bits => 3-21 => absolute value of topmost tick\\n    /// Next 30 bits => 22-51 => current branch ID\\n    /// Next 30 bits => 52-81 => total branch ID\\n    /// Next 64 bits => 82-145 => Total supply\\n    /// Next 64 bits => 146-209 => Total borrow\\n    /// Next 32 bits => 210-241 => Total positions\\n    uint256 internal vaultVariables;\\n\\n    /// note: vaultVariables2 contains variables which do not update on every transaction. So mainly admin/auth set amount\\n    /// First 16 bits => 0-15 => supply rate magnifier; 10000 = 1x (Here 16 bits should be more than enough)\\n    /// Next 16 bits => 16-31 => borrow rate magnifier; 10000 = 1x (Here 16 bits should be more than enough)\\n    /// Next 10 bits => 32-41 => collateral factor. 800 = 0.8 = 80% (max precision of 0.1%)\\n    /// Next 10 bits => 42-51 => liquidation Threshold. 900 = 0.9 = 90% (max precision of 0.1%)\\n    /// Next 10 bits => 52-61 => liquidation Max Limit. 950 = 0.95 = 95% (max precision of 0.1%) (above this 100% liquidation can happen)\\n    /// Next 10 bits => 62-71 => withdraw gap. 100 = 0.1 = 10%. (max precision of 0.1%) (max 7 bits can also suffice for the requirement here of 0.1% to 10%). Needed to save some limits on withdrawals so liquidate can work seamlessly.\\n    /// Next 10 bits => 72-81 => liquidation penalty. 100 = 0.01 = 1%. (max precision of 0.01%) (max liquidation penantly can be 10.23%). Applies when tick is in between liquidation Threshold & liquidation Max Limit.\\n    /// Next 10 bits => 82-91 => borrow fee. 100 = 0.01 = 1%. (max precision of 0.01%) (max borrow fee can be 10.23%). Fees on borrow.\\n    /// Next 4  bits => 92-95 => empty\\n    /// Next 160 bits => 96-255 => Oracle address\\n    uint256 internal vaultVariables2;\\n\\n    /// note: stores absorbed liquidity\\n    /// First 128 bits raw debt amount\\n    /// last 128 bits raw col amount\\n    uint256 internal absorbedLiquidity;\\n\\n    /// position index => position data uint\\n    /// if the entire variable is 0 (meaning not initialized) at the start that means no position at all\\n    /// First 1 bit => 0 => position type (0 => borrow position; 1 => supply position)\\n    /// Next 1 bit => 1 => sign of user's tick (0 => negative; 1 => positive)\\n    /// Next 19 bits => 2-20 => absolute value of user's tick\\n    /// Next 24 bits => 21-44 => user's tick's id\\n    /// Below we are storing user's collateral & not debt, because the position can also be only collateral with no tick but it can never be only debt\\n    /// Next 64 bits => 45-108 => user's supply amount. Debt will be calculated through supply & ratio.\\n    /// Next 64 bits => 109-172 => user's dust debt amount. User's net debt = total debt - dust amount. Total debt is calculated through supply & ratio\\n    /// User won't pay any extra interest on dust debt & hence we will not show it as a debt on UI. For user's there's no dust.\\n    mapping(uint256 => uint256) internal positionData;\\n\\n    /// Tick has debt only keeps data of non liquidated positions. liquidated tick's data stays in branch itself\\n    /// tick parent => uint (represents bool for 256 children)\\n    /// parent of (i)th tick:-\\n    /// if (i>=0) (i / 256);\\n    /// else ((i + 1) / 256) - 1\\n    /// first bit of the variable is the smallest tick & last bit is the biggest tick of that slot\\n    mapping(int256 => uint256) internal tickHasDebt;\\n\\n    /// mapping tickId => tickData\\n    /// Tick related data. Total debt & other things\\n    /// First bit => 0 => If 1 then liquidated else not liquidated\\n    /// Next 24 bits => 1-24 => Total IDs. ID should start from 1.\\n    /// If not liquidated:\\n    /// Next 64 bits => 25-88 => raw debt\\n    /// If liquidated\\n    /// The below 3 things are of last ID. This is to be updated when user creates a new position\\n    /// Next 1 bit => 25 => Is 100% liquidated? If this is 1 meaning it was above max tick when it got liquidated (100% liquidated)\\n    /// Next 30 bits => 26-55 => branch ID where this tick got liquidated\\n    /// Next 50 bits => 56-105 => debt factor 50 bits (35 bits coefficient | 15 bits expansion)\\n    mapping(int256 => uint256) internal tickData;\\n\\n    /// tick id => previous tick id liquidation data. ID starts from 1\\n    /// One tick ID contains 3 IDs of 80 bits in it, holding liquidation data of previously active but liquidated ticks\\n    /// 81 bits data below\\n    /// #### First 85 bits ####\\n    /// 1st bit => 0 => Is 100% liquidated? If this is 1 meaning it was above max tick when it got liquidated\\n    /// Next 30 bits => 1-30 => branch ID where this tick got liquidated\\n    /// Next 50 bits => 31-80 => debt factor 50 bits (35 bits coefficient | 15 bits expansion)\\n    /// #### Second 85 bits ####\\n    /// 85th bit => 85 => Is 100% liquidated? If this is 1 meaning it was above max tick when it got liquidated\\n    /// Next 30 bits => 86-115 => branch ID where this tick got liquidated\\n    /// Next 50 bits => 116-165 => debt factor 50 bits (35 bits coefficient | 15 bits expansion)\\n    /// #### Third 85 bits ####\\n    /// 170th bit => 170 => Is 100% liquidated? If this is 1 meaning it was above max tick when it got liquidated\\n    /// Next 30 bits => 171-200 => branch ID where this tick got liquidated\\n    /// Next 50 bits => 201-250 => debt factor 50 bits (35 bits coefficient | 15 bits expansion)\\n    mapping(int256 => mapping(uint256 => uint256)) internal tickId;\\n\\n    /// mapping branchId => branchData\\n    /// First 2 bits => 0-1 => if 0 then not liquidated, if 1 then liquidated, if 2 then merged, if 3 then closed\\n    /// merged means the branch is merged into it's base branch\\n    /// closed means all the users are 100% liquidated\\n    /// Next 1 bit => 2 => minima tick sign of this branch. Will only be there if any liquidation happened.\\n    /// Next 19 bits => 3-21 => minima tick of this branch. Will only be there if any liquidation happened.\\n    /// Next 30 bits => 22-51 => Partials of minima tick of branch this is connected to. 0 if master branch.\\n    /// Next 64 bits => 52-115 Debt liquidity at this branch. Similar to last's top tick data. Remaining debt will move here from tickData after first liquidation\\n    /// If not merged\\n    /// Next 50 bits => 116-165 => Debt factor or of this branch. (35 bits coefficient | 15 bits expansion)\\n    /// If merged\\n    /// Next 50 bits => 116-165 => Connection/adjustment debt factor of this branch with the next branch.\\n    /// If closed\\n    /// Next 50 bits => 116-165 => Debt factor as 0. As all the user's positions are now fully gone\\n    /// following values are present always again (merged / not merged / closed)\\n    /// Next 30 bits => 166-195 => Branch's ID with which this branch is connected. If 0 then that means this is the master branch\\n    /// Next 1 bit => 196 => sign of minima tick of branch this is connected to. 0 if master branch.\\n    /// Next 19 bits => 197-215 => minima tick of branch this is connected to. 0 if master branch.\\n    mapping(uint256 => uint256) internal branchData;\\n\\n    /// Exchange prices are in 1e12\\n    /// First 64 bits => 0-63 => Liquidity's collateral token supply exchange price\\n    /// First 64 bits => 64-127 => Liquidity's debt token borrow exchange price\\n    /// First 64 bits => 128-191 => Vault's collateral token supply exchange price\\n    /// First 64 bits => 192-255 => Vault's debt token borrow exchange price\\n    uint256 internal rates;\\n\\n    /// address of rebalancer\\n    address internal rebalancer;\\n\\n    uint256 internal absorbedDustDebt;\\n}\\n\",\"keccak256\":\"0x446a2d8d47d53d1584a1a1dd9aed247320ba04582e8bbcd7be60c979f908c52e\",\"license\":\"BUSL-1.1\"},\"contracts/protocols/vault/vaultT1/coreModule/constantVariables.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nimport { IFluidVaultFactory } from \\\"../../interfaces/iVaultFactory.sol\\\";\\nimport { IFluidLiquidity } from \\\"../../../../liquidity/interfaces/iLiquidity.sol\\\";\\nimport { StorageRead } from \\\"../../../../libraries/storageRead.sol\\\";\\n\\nimport { Structs } from \\\"./structs.sol\\\";\\n\\ninterface TokenInterface {\\n    function decimals() external view returns (uint8);\\n}\\n\\ncontract ConstantVariables is StorageRead, Structs {\\n    /***********************************|\\n    |        Constant Variables         |\\n    |__________________________________*/\\n\\n    address internal constant NATIVE_TOKEN = 0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE;\\n    /// @dev collateral token address\\n    address internal immutable SUPPLY_TOKEN;\\n    /// @dev borrow token address\\n    address internal immutable BORROW_TOKEN;\\n\\n    /// @dev Token decimals. For example wETH is 18 decimals\\n    uint8 internal immutable SUPPLY_DECIMALS;\\n    /// @dev Token decimals. For example USDC is 6 decimals\\n    uint8 internal immutable BORROW_DECIMALS;\\n\\n    /// @dev VaultT1 AdminModule implemenation address\\n    address internal immutable ADMIN_IMPLEMENTATION;\\n\\n    /// @dev VaultT1 Secondary implemenation (main2.sol) address\\n    address internal immutable SECONDARY_IMPLEMENTATION;\\n\\n    /// @dev liquidity proxy contract address\\n    IFluidLiquidity public immutable LIQUIDITY;\\n\\n    /// @dev vault factory contract address\\n    IFluidVaultFactory public immutable VAULT_FACTORY;\\n\\n    uint public immutable VAULT_ID;\\n\\n    uint internal constant X8 = 0xff;\\n    uint internal constant X10 = 0x3ff;\\n    uint internal constant X16 = 0xffff;\\n    uint internal constant X19 = 0x7ffff;\\n    uint internal constant X20 = 0xfffff;\\n    uint internal constant X24 = 0xffffff;\\n    uint internal constant X25 = 0x1ffffff;\\n    uint internal constant X30 = 0x3fffffff;\\n    uint internal constant X35 = 0x7ffffffff;\\n    uint internal constant X50 = 0x3ffffffffffff;\\n    uint internal constant X64 = 0xffffffffffffffff;\\n    uint internal constant X96 = 0xffffffffffffffffffffffff;\\n    uint internal constant X128 = 0xffffffffffffffffffffffffffffffff;\\n\\n    uint256 internal constant EXCHANGE_PRICES_PRECISION = 1e12;\\n\\n    /// @dev slot ids in Liquidity contract. Helps in low gas fetch from liquidity contract by skipping delegate call\\n    bytes32 internal immutable LIQUIDITY_SUPPLY_EXCHANGE_PRICE_SLOT;\\n    bytes32 internal immutable LIQUIDITY_BORROW_EXCHANGE_PRICE_SLOT;\\n    bytes32 internal immutable LIQUIDITY_USER_SUPPLY_SLOT;\\n    bytes32 internal immutable LIQUIDITY_USER_BORROW_SLOT;\\n\\n    /// @notice returns all Vault constants\\n    function constantsView() external view returns (ConstantViews memory constantsView_) {\\n        constantsView_.liquidity = address(LIQUIDITY);\\n        constantsView_.factory = address(VAULT_FACTORY);\\n        constantsView_.adminImplementation = ADMIN_IMPLEMENTATION;\\n        constantsView_.secondaryImplementation = SECONDARY_IMPLEMENTATION;\\n        constantsView_.supplyToken = SUPPLY_TOKEN;\\n        constantsView_.borrowToken = BORROW_TOKEN;\\n        constantsView_.supplyDecimals = SUPPLY_DECIMALS;\\n        constantsView_.borrowDecimals = BORROW_DECIMALS;\\n        constantsView_.vaultId = VAULT_ID;\\n        constantsView_.liquiditySupplyExchangePriceSlot = LIQUIDITY_SUPPLY_EXCHANGE_PRICE_SLOT;\\n        constantsView_.liquidityBorrowExchangePriceSlot = LIQUIDITY_BORROW_EXCHANGE_PRICE_SLOT;\\n        constantsView_.liquidityUserSupplySlot = LIQUIDITY_USER_SUPPLY_SLOT;\\n        constantsView_.liquidityUserBorrowSlot = LIQUIDITY_USER_BORROW_SLOT;\\n    }\\n\\n    constructor(ConstantViews memory constants_) {\\n        LIQUIDITY = IFluidLiquidity(constants_.liquidity);\\n        VAULT_FACTORY = IFluidVaultFactory(constants_.factory);\\n        VAULT_ID = constants_.vaultId;\\n\\n        SUPPLY_TOKEN = constants_.supplyToken;\\n        BORROW_TOKEN = constants_.borrowToken;\\n        SUPPLY_DECIMALS = constants_.supplyDecimals;\\n        BORROW_DECIMALS = constants_.borrowDecimals;\\n\\n        // @dev those slots are calculated in the deploymentLogics / VaultFactory\\n        LIQUIDITY_SUPPLY_EXCHANGE_PRICE_SLOT = constants_.liquiditySupplyExchangePriceSlot;\\n        LIQUIDITY_BORROW_EXCHANGE_PRICE_SLOT = constants_.liquidityBorrowExchangePriceSlot;\\n        LIQUIDITY_USER_SUPPLY_SLOT = constants_.liquidityUserSupplySlot;\\n        LIQUIDITY_USER_BORROW_SLOT = constants_.liquidityUserBorrowSlot;\\n\\n        ADMIN_IMPLEMENTATION = constants_.adminImplementation;\\n        SECONDARY_IMPLEMENTATION = constants_.secondaryImplementation;\\n    }\\n}\\n\",\"keccak256\":\"0x30bb94d713254816c679c77ccaeef964608edf6cc3acdcd1f73eff0185fcd26e\",\"license\":\"BUSL-1.1\"},\"contracts/protocols/vault/vaultT1/coreModule/events.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\ncontract Events {\\n    /// @notice emitted when an operate() method is executed that changes collateral (`colAmt_`) / debt (debtAmt_`)\\n    /// amount for a `user_` position with `nftId_`. Receiver of any funds is the address `to_`.\\n    event LogOperate(address user_, uint256 nftId_, int256 colAmt_, int256 debtAmt_, address to_);\\n\\n    /// @notice emitted when the exchange prices are updated in storage.\\n    event LogUpdateExchangePrice(uint256 supplyExPrice_, uint256 borrowExPrice_);\\n\\n    /// @notice emitted when a liquidation has been executed.\\n    event LogLiquidate(address liquidator_, uint256 colAmt_, uint256 debtAmt_, address to_);\\n\\n    /// @notice emitted when `absorb()` was executed to absorb bad debt.\\n    event LogAbsorb(uint colAbsorbedRaw_, uint debtAbsorbedRaw_);\\n\\n    /// @notice emitted when a `rebalance()` has been executed, balancing out total supply / borrow between Vault\\n    /// and Fluid Liquidity pools.\\n    /// if `colAmt_` is positive then profit, meaning withdrawn from vault and sent to rebalancer address.\\n    /// if `colAmt_` is negative then loss, meaning transfer from rebalancer address to vault and deposit.\\n    /// if `debtAmt_` is positive then profit, meaning borrow from vault and sent to rebalancer address.\\n    /// if `debtAmt_` is negative then loss, meaning transfer from rebalancer address to vault and payback.\\n    event LogRebalance(int colAmt_, int debtAmt_);\\n}\\n\",\"keccak256\":\"0x98e1763be5df784b6deb3437abf15b200fe569e46ee931c31a9228b27bc5b23f\",\"license\":\"BUSL-1.1\"},\"contracts/protocols/vault/vaultT1/coreModule/helpers.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nimport { Variables } from \\\"../common/variables.sol\\\";\\nimport { ConstantVariables } from \\\"./constantVariables.sol\\\";\\nimport { Events } from \\\"./events.sol\\\";\\nimport { TickMath } from \\\"../../../../libraries/tickMath.sol\\\";\\nimport { BigMathMinified } from \\\"../../../../libraries/bigMathMinified.sol\\\";\\nimport { BigMathVault } from \\\"../../../../libraries/bigMathVault.sol\\\";\\nimport { LiquidityCalcs } from \\\"../../../../libraries/liquidityCalcs.sol\\\";\\n\\nimport { ErrorTypes } from \\\"../../errorTypes.sol\\\";\\nimport { Error } from \\\"../../error.sol\\\";\\n\\n/// @dev Fluid vault protocol helper methods. Mostly used for `operate()` and `liquidate()` methods of CoreModule.\\nabstract contract Helpers is Variables, ConstantVariables, Events, Error {\\n    using BigMathMinified for uint256;\\n    using BigMathVault for uint256;\\n\\n    /// @notice Calculates new vault exchange prices. Does not update values in storage.\\n    /// @param vaultVariables2_ exactly same as vaultVariables2 from storage\\n    /// @return liqSupplyExPrice_ latest liquidity's supply token supply exchange price\\n    /// @return liqBorrowExPrice_ latest liquidity's borrow token borrow exchange price\\n    /// @return vaultSupplyExPrice_ latest vault's supply token exchange price\\n    /// @return vaultBorrowExPrice_ latest vault's borrow token exchange price\\n    function updateExchangePrices(\\n        uint256 vaultVariables2_\\n    )\\n        public\\n        view\\n        returns (\\n            uint256 liqSupplyExPrice_,\\n            uint256 liqBorrowExPrice_,\\n            uint256 vaultSupplyExPrice_,\\n            uint256 vaultBorrowExPrice_\\n        )\\n    {\\n        // Fetching last stored rates\\n        uint rates_ = rates;\\n\\n        (liqSupplyExPrice_, ) = LiquidityCalcs.calcExchangePrices(\\n            LIQUIDITY.readFromStorage(LIQUIDITY_SUPPLY_EXCHANGE_PRICE_SLOT)\\n        );\\n        (, liqBorrowExPrice_) = LiquidityCalcs.calcExchangePrices(\\n            LIQUIDITY.readFromStorage(LIQUIDITY_BORROW_EXCHANGE_PRICE_SLOT)\\n        );\\n\\n        uint256 oldLiqSupplyExPrice_ = (rates_ & X64);\\n        uint256 oldLiqBorrowExPrice_ = ((rates_ >> 64) & X64);\\n        if (liqSupplyExPrice_ < oldLiqSupplyExPrice_ || liqBorrowExPrice_ < oldLiqBorrowExPrice_) {\\n            // new liquidity exchange price is < than the old one. liquidity exchange price should only ever increase.\\n            // If not, something went wrong and avoid proceeding with unknown outcome.\\n            revert FluidVaultError(ErrorTypes.VaultT1__LiquidityExchangePriceUnexpected);\\n        }\\n\\n        // liquidity Exchange Prices always increases in next block. Hence substraction with old will never be negative\\n        // uint64 * 1e18 is the max the number that could be\\n        unchecked {\\n            // Calculating increase in supply exchange price w.r.t last stored liquidity's exchange price\\n            // vaultSupplyExPrice_ => supplyIncreaseInPercent_\\n            vaultSupplyExPrice_ = ((((liqSupplyExPrice_ * 1e18) / oldLiqSupplyExPrice_) - 1e18) *\\n                (vaultVariables2_ & X16)) / 10000; // supply rate magnifier\\n\\n            // Calculating increase in borrow exchange price w.r.t last stored liquidity's exchange price\\n            // vaultBorrowExPrice_ => borrowIncreaseInPercent_\\n            vaultBorrowExPrice_ = ((((liqBorrowExPrice_ * 1e18) / oldLiqBorrowExPrice_) - 1e18) *\\n                ((vaultVariables2_ >> 16) & X16)) / 10000; // borrow rate magnifier\\n\\n            // It's extremely hard the exchange prices to overflow even in 100 years but if it does it's not an\\n            // issue here as we are not updating on storage\\n            // (rates_ >> 128) & X64) -> last stored vault's supply token exchange price\\n            vaultSupplyExPrice_ = (((rates_ >> 128) & X64) * (1e18 + vaultSupplyExPrice_)) / 1e18;\\n            // (rates_ >> 192) -> last stored vault's borrow token exchange price (no need to mask with & X64 as it is anyway max 64 bits)\\n            vaultBorrowExPrice_ = ((rates_ >> 192) * (1e18 + vaultBorrowExPrice_)) / 1e18;\\n        }\\n    }\\n\\n    /// note admin module is also calling this function self call\\n    /// @dev updating exchange price on storage. Only need to update on storage when changing supply or borrow magnifier\\n    function updateExchangePricesOnStorage()\\n        public\\n        returns (\\n            uint256 liqSupplyExPrice_,\\n            uint256 liqBorrowExPrice_,\\n            uint256 vaultSupplyExPrice_,\\n            uint256 vaultBorrowExPrice_\\n        )\\n    {\\n        (liqSupplyExPrice_, liqBorrowExPrice_, vaultSupplyExPrice_, vaultBorrowExPrice_) = updateExchangePrices(\\n            vaultVariables2\\n        );\\n\\n        if (\\n            liqSupplyExPrice_ > X64 || liqBorrowExPrice_ > X64 || vaultSupplyExPrice_ > X64 || vaultBorrowExPrice_ > X64\\n        ) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__ExchangePriceOverFlow);\\n        }\\n\\n        // Updating in storage\\n        rates =\\n            liqSupplyExPrice_ |\\n            (liqBorrowExPrice_ << 64) |\\n            (vaultSupplyExPrice_ << 128) |\\n            (vaultBorrowExPrice_ << 192);\\n\\n        emit LogUpdateExchangePrice(vaultSupplyExPrice_, vaultBorrowExPrice_);\\n    }\\n\\n    /// @dev fetches new user's position after liquidation. The new liquidated position's debt is decreased by 0.01%\\n    /// to make sure that branch's liquidity never becomes 0 as if it would have gotten 0 then there will be multiple cases that we would need to tackle.\\n    /// @param positionTick_ position's tick when it was last updated through operate\\n    /// @param positionTickId_ position's tick Id. This stores the debt factor and branch to make the first connection\\n    /// @param positionRawDebt_ position's raw debt when it was last updated through operate\\n    /// @param tickData_ position's tick's tickData just for minor comparison to know if data is moved to tick Id or is still in tick data\\n    /// @return final tick position after all the liquidation\\n    /// @return final debt of position after all the liquidation\\n    /// @return positionRawCol_ final collateral of position after all the liquidation\\n    /// @return branchId_ final branch's ID where the position is at currently\\n    /// @return branchData_ final branch's data where the position is at currently\\n    function fetchLatestPosition(\\n        int256 positionTick_,\\n        uint256 positionTickId_,\\n        uint256 positionRawDebt_,\\n        uint256 tickData_\\n    )\\n        public\\n        view\\n        returns (\\n            int256, // positionTick_\\n            uint256, // positionRawDebt_\\n            uint256 positionRawCol_,\\n            uint256 branchId_,\\n            uint256 branchData_\\n        )\\n    {\\n        uint256 initialPositionRawDebt_ = positionRawDebt_;\\n        uint256 connectionFactor_;\\n        bool isFullyLiquidated_;\\n\\n        // Checking if tick's total ID = user's tick ID\\n        if (((tickData_ >> 1) & X24) == positionTickId_) {\\n            // fetching from tick data itself\\n            isFullyLiquidated_ = ((tickData_ >> 25) & 1) == 1;\\n            branchId_ = (tickData_ >> 26) & X30;\\n            connectionFactor_ = (tickData_ >> 56) & X50;\\n        } else {\\n            {\\n                uint256 tickLiquidationData_;\\n                unchecked {\\n                    // Fetching tick's liquidation data. One variable contains data of 3 IDs. Tick Id mapping is starting from 1.\\n                    tickLiquidationData_ =\\n                        tickId[positionTick_][(positionTickId_ + 2) / 3] >>\\n                        (((positionTickId_ + 2) % 3) * 85);\\n                }\\n\\n                isFullyLiquidated_ = (tickLiquidationData_ & 1) == 1;\\n                branchId_ = (tickLiquidationData_ >> 1) & X30;\\n                connectionFactor_ = (tickLiquidationData_ >> 31) & X50;\\n            }\\n        }\\n\\n        // data of branch\\n        branchData_ = branchData[branchId_];\\n\\n        if (isFullyLiquidated_) {\\n            positionTick_ = type(int).min;\\n            positionRawDebt_ = 0;\\n        } else {\\n            // Below information about connection debt factor\\n            // If branch is merged, Connection debt factor is used to multiply in order to get perfect liquidation of user\\n            // For example: Considering user was at the top.\\n            // In first branch, the user liquidated to debt factor 0.5 and then branch got merged (branching starting from 1)\\n            // In second branch, it got liquidated to 0.4 but when the above branch merged the debt factor on this branch was 0.6\\n            // Meaning on 1st branch, user got liquidated by 50% & on 2nd by 33.33%. So a total of 66.6%.\\n            // What we will set a connection factor will be 0.6/0.5 = 1.2\\n            // So now to get user's position, this is what we'll do:\\n            // finalDebt = (0.4 / (1 * 1.2)) * debtBeforeLiquidation\\n            // 0.4 is current active branch's minima debt factor\\n            // 1 is debt factor from where user started\\n            // 1.2 is connection factor which we found out through 0.6 / 0.5\\n            while ((branchData_ & 3) == 2) {\\n                // If true then the branch is merged\\n\\n                // userTickDebtFactor * connectionDebtFactor *... connectionDebtFactor aka adjustmentDebtFactor\\n                connectionFactor_ = connectionFactor_.mulBigNumber(((branchData_ >> 116) & X50));\\n                if (connectionFactor_ == BigMathVault.MAX_MASK_DEBT_FACTOR) break; // user ~100% liquidated\\n                // Note we don't need updated branch data in case of 100% liquidated so saving gas for fetching it\\n\\n                // Fetching new branch data\\n                branchId_ = (branchData_ >> 166) & X30; // Link to base branch of current branch\\n                branchData_ = branchData[branchId_];\\n            }\\n            // When the while loop breaks meaning the branch now has minima Debt Factor or is a closed branch;\\n\\n            if (((branchData_ & 3) == 3) || (connectionFactor_ == BigMathVault.MAX_MASK_DEBT_FACTOR)) {\\n                // Branch got closed (or user liquidated ~100%). Hence make the user's position 0\\n                // Rare cases to get into this situation\\n                // Branch can get close often but once closed it's tricky that some user might come iterating through there\\n                // If a user comes then that user will be very mini user like some cents probably\\n                positionTick_ = type(int).min;\\n                positionRawDebt_ = 0;\\n            } else {\\n                // If branch is not merged, the main branch it's connected to then it'll have minima debt factor\\n\\n                // position debt = debt * base branch minimaDebtFactor / connectionFactor\\n                positionRawDebt_ = positionRawDebt_.mulDivNormal(\\n                    (branchData_ >> 116) & X50, // minimaDebtFactor\\n                    connectionFactor_\\n                );\\n\\n                unchecked {\\n                    // Reducing user's liquidity by 0.01% if user got liquidated.\\n                    // As this will make sure that the branch always have some debt even if all liquidated user left\\n                    // This saves a lot more logics & consideration on Operate function\\n                    // if we don't do this then we have to add logics related to closing the branch and factor connections accordingly.\\n                    if (positionRawDebt_ > (initialPositionRawDebt_ / 100)) {\\n                        positionRawDebt_ = (positionRawDebt_ * 9999) / 10000;\\n                    } else {\\n                        // if user debt reduced by more than 99% in liquidation then making user as fully liquidated\\n                        positionRawDebt_ = 0;\\n                    }\\n                }\\n\\n                {\\n                    if (positionRawDebt_ > 0) {\\n                        // positionTick_ -> read minima tick of branch\\n                        unchecked {\\n                            positionTick_ = branchData_ & 4 == 4\\n                                ? int((branchData_ >> 3) & X19)\\n                                : -int((branchData_ >> 3) & X19);\\n                        }\\n                        // Calculating user's collateral\\n                        uint256 ratioAtTick_ = TickMath.getRatioAtTick(int24(positionTick_));\\n                        uint256 ratioOneLess_;\\n                        unchecked {\\n                            ratioOneLess_ = (ratioAtTick_ * 10000) / 10015;\\n                        }\\n                        // formula below for better readability:\\n                        // length = ratioAtTick_ - ratioOneLess_\\n                        // ratio = ratioOneLess_ + (length * positionPartials_) / X30\\n                        // positionRawCol_ = (positionRawDebt_ * (1 << 96)) / ratio_\\n                        positionRawCol_ =\\n                            (positionRawDebt_ * TickMath.ZERO_TICK_SCALED_RATIO) /\\n                            (ratioOneLess_ + ((ratioAtTick_ - ratioOneLess_) * ((branchData_ >> 22) & X30)) / X30);\\n                    } else {\\n                        positionTick_ = type(int).min;\\n                    }\\n                }\\n            }\\n        }\\n        return (positionTick_, positionRawDebt_, positionRawCol_, branchId_, branchData_);\\n    }\\n\\n    /// @dev sets `tick_` as having debt or no debt in storage `tickHasDebt` depending on `addOrRemove_`\\n    /// @param tick_ tick to add or remove from tickHasDebt\\n    /// @param addOrRemove_ if true then add else remove\\n    function _updateTickHasDebt(int tick_, bool addOrRemove_) internal {\\n        // Positive mapID_ starts from 0 & above and negative starts below 0.\\n        // tick 0 to 255 will have mapId_ as 0 while tick -256 to -1 will have mapId_ as -1.\\n        unchecked {\\n            int mapId_ = tick_ < 0 ? ((tick_ + 1) / 256) - 1 : tick_ / 256;\\n\\n            // in case of removing:\\n            // (tick == 255) tickHasDebt[mapId_] - 1 << 255\\n            // (tick == 0) tickHasDebt[mapId_] - 1 << 0\\n            // (tick == -1) tickHasDebt[mapId_] - 1 << 255\\n            // (tick == -256) tickHasDebt[mapId_] - 1 << 0\\n            // in case of adding:\\n            // (tick == 255) tickHasDebt[mapId_] - 1 << 255\\n            // (tick == 0) tickHasDebt[mapId_] - 1 << 0\\n            // (tick == -1) tickHasDebt[mapId_] - 1 << 255\\n            // (tick == -256) tickHasDebt[mapId_] - 1 << 0\\n            uint position_ = uint(tick_ - (mapId_ * 256));\\n\\n            tickHasDebt[mapId_] = addOrRemove_\\n                ? tickHasDebt[mapId_] | (1 << position_)\\n                : tickHasDebt[mapId_] & ~(1 << position_);\\n        }\\n    }\\n\\n    /// @dev gets next perfect top tick (tick which is not liquidated)\\n    /// @param topTick_ current top tick which will no longer be top tick\\n    /// @return nextTick_ next top tick which will become the new top tick\\n    function _fetchNextTopTick(int topTick_) internal view returns (int nextTick_) {\\n        int mapId_;\\n        uint tickHasDebt_;\\n\\n        unchecked {\\n            mapId_ = topTick_ < 0 ? ((topTick_ + 1) / 256) - 1 : topTick_ / 256;\\n            uint bitsToRemove_ = uint(-topTick_ + (mapId_ * 256 + 256));\\n            // Removing current top tick from tickHasDebt\\n            tickHasDebt_ = (tickHasDebt[mapId_] << bitsToRemove_) >> bitsToRemove_;\\n\\n            // For last user remaining in vault there could be a lot of iterations in the while loop.\\n            // Chances of this to happen is extremely low (like ~0%)\\n            while (true) {\\n                if (tickHasDebt_ > 0) {\\n                    nextTick_ = mapId_ * 256 + int(tickHasDebt_.mostSignificantBit()) - 1;\\n                    break;\\n                }\\n\\n                // Reducing mapId_ by 1 in every loop; if it reaches to -129 then no filled tick exist, meaning it's the last tick\\n                if (--mapId_ == -129) {\\n                    nextTick_ = type(int).min;\\n                    break;\\n                }\\n\\n                tickHasDebt_ = tickHasDebt[mapId_];\\n            }\\n        }\\n    }\\n\\n    /// @dev adding debt to a particular tick\\n    /// @param totalColRaw_ total raw collateral of position\\n    /// @param netDebtRaw_ net raw debt (total debt - dust debt)\\n    /// @return tick_ tick where the debt is being added\\n    /// @return tickId_ tick current id\\n    /// @return userRawDebt_ user's total raw debt\\n    /// @return rawDust_ dust debt used for adjustment\\n    function _addDebtToTickWrite(\\n        uint256 totalColRaw_,\\n        uint256 netDebtRaw_ // debtRaw - dust\\n    ) internal returns (int256 tick_, uint256 tickId_, uint256 userRawDebt_, uint256 rawDust_) {\\n        if (netDebtRaw_ < 10000) {\\n            // thrown if user's debt is too low\\n            revert FluidVaultError(ErrorTypes.VaultT1__UserDebtTooLow);\\n        }\\n        // tick_ & ratio_ returned from library is round down. Hence increasing it by 1 and increasing ratio by 1 tick.\\n        uint ratio_ = (netDebtRaw_ * TickMath.ZERO_TICK_SCALED_RATIO) / totalColRaw_;\\n        (tick_, ratio_) = TickMath.getTickAtRatio(ratio_);\\n        unchecked {\\n            ++tick_;\\n            ratio_ = (ratio_ * 10015) / 10000;\\n        }\\n        userRawDebt_ = (ratio_ * totalColRaw_) >> 96;\\n        rawDust_ = userRawDebt_ - netDebtRaw_;\\n\\n        // Current state of tick\\n        uint256 tickData_ = tickData[tick_];\\n        tickId_ = (tickData_ >> 1) & X24;\\n\\n        uint tickNewDebt_;\\n        if (tickId_ > 0 && tickData_ & 1 == 0) {\\n            // Current debt in the tick\\n            uint256 tickExistingRawDebt_ = (tickData_ >> 25) & X64;\\n            tickExistingRawDebt_ = (tickExistingRawDebt_ >> 8) << (tickExistingRawDebt_ & X8);\\n\\n            // Tick's already initialized and not liquidated. Hence simply add the debt\\n            tickNewDebt_ = tickExistingRawDebt_ + userRawDebt_;\\n            if (tickExistingRawDebt_ == 0) {\\n                // Adding tick into tickHasDebt\\n                _updateTickHasDebt(tick_, true);\\n            }\\n        } else {\\n            // Liquidation happened or tick getting initialized for the very first time.\\n            if (tickId_ > 0) {\\n                // Meaning a liquidation happened. Hence move the data to tickID\\n                unchecked {\\n                    uint tickMap_ = (tickId_ + 2) / 3;\\n                    // Adding 2 in ID so we can get right mapping ID. For example for ID 1, 2 & 3 mapping should be 1 and so on..\\n                    // For example shift for id 1 should be 0, for id 2 should be 85, for id 3 it should be 170 and so on..\\n                    tickId[tick_][tickMap_] =\\n                        tickId[tick_][tickMap_] |\\n                        ((tickData_ >> 25) << (((tickId_ + 2) % 3) * 85));\\n                }\\n            }\\n            // Increasing total ID by one\\n            unchecked {\\n                ++tickId_;\\n            }\\n            tickNewDebt_ = userRawDebt_;\\n\\n            // Adding tick into tickHasDebt\\n            _updateTickHasDebt(tick_, true);\\n        }\\n        if (tickNewDebt_ < 10000) {\\n            // thrown if tick's debt/liquidity is too low\\n            revert FluidVaultError(ErrorTypes.VaultT1__TickDebtTooLow);\\n        }\\n        tickData[tick_] = (tickId_ << 1) | (tickNewDebt_.toBigNumber(56, 8, BigMathMinified.ROUND_DOWN) << 25);\\n    }\\n\\n    /// @dev sets new top tick. If it comes to this function then that means current top tick is perfect tick.\\n    /// if next top tick is liquidated then unitializes the current non liquidated branch and make the liquidated branch as current branch\\n    /// @param topTick_ current top tick\\n    /// @param vaultVariables_ vaultVariables of storage but with newer updates\\n    /// @return newVaultVariables_ newVaultVariables_ updated vault variable internally to this function\\n    /// @return newTopTick_ new top tick\\n    function _setNewTopTick(\\n        int topTick_,\\n        uint vaultVariables_\\n    ) internal returns (uint newVaultVariables_, int newTopTick_) {\\n        // This function considers that the current top tick was not liquidated\\n        // Overall flow of function:\\n        // if new top tick liquidated (aka base branch's minima tick) -> Close the current branch and make base branch as current branch\\n        // if new top tick not liquidated -> update things in current branch.\\n        // if new top tick is not liquidated and same tick exist in base branch then tick is considered as not liquidated.\\n\\n        uint branchId_ = (vaultVariables_ >> 22) & X30; // branch id of current branch\\n\\n        uint256 branchData_ = branchData[branchId_];\\n        int256 baseBranchMinimaTick_;\\n        if ((branchData_ >> 196) & 1 == 1) {\\n            baseBranchMinimaTick_ = int((branchData_ >> 197) & X19);\\n        } else {\\n            unchecked {\\n                baseBranchMinimaTick_ = -int((branchData_ >> 197) & X19);\\n            }\\n            if (baseBranchMinimaTick_ == 0) {\\n                // meaning the current branch is the master branch\\n                baseBranchMinimaTick_ = type(int).min;\\n            }\\n        }\\n\\n        // Returns type(int).min if no top tick exist\\n        int nextTopTickNotLiquidated_ = _fetchNextTopTick(topTick_);\\n\\n        newTopTick_ = baseBranchMinimaTick_ > nextTopTickNotLiquidated_\\n            ? baseBranchMinimaTick_\\n            : nextTopTickNotLiquidated_;\\n\\n        if (newTopTick_ == type(int).min) {\\n            // if this happens that means this was the last user of the vault :(\\n            vaultVariables_ = vaultVariables_ & 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffc00001;\\n        } else if (newTopTick_ == nextTopTickNotLiquidated_) {\\n            // New top tick exist in current non liquidated branch\\n            if (newTopTick_ < 0) {\\n                unchecked {\\n                    vaultVariables_ =\\n                        (vaultVariables_ & 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffc00001) |\\n                        (uint(-newTopTick_) << 3);\\n                }\\n            } else {\\n                vaultVariables_ =\\n                    (vaultVariables_ & 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffc00001) |\\n                    4 | // setting top tick as positive\\n                    (uint(newTopTick_) << 3);\\n            }\\n        } else {\\n            // if this happens that means base branch exists & is the next top tick\\n            // Remove current non liquidated branch as active.\\n            // Not deleting here as it's going to get initialize again whenever a new top tick comes\\n            branchData[branchId_] = 0;\\n            // Inserting liquidated branch's minima tick\\n            unchecked {\\n                vaultVariables_ =\\n                    (vaultVariables_ & 0xfffffffffffffffffffffffffffffffffffffffffffc00000000000000000001) |\\n                    2 | // Setting top tick as liquidated\\n                    (((branchData_ >> 196) & X20) << 2) | // new current top tick = base branch minima tick\\n                    (((branchData_ >> 166) & X30) << 22) | // new current branch id = base branch id\\n                    ((branchId_ - 1) << 52); // reduce total branch id by 1\\n            }\\n        }\\n\\n        newVaultVariables_ = vaultVariables_;\\n    }\\n\\n    constructor(ConstantViews memory constants_) ConstantVariables(constants_) {}\\n}\\n\",\"keccak256\":\"0xbcbd186a0c739caf614f5a21e6e6171c2bd6d9048e66900d5a6347405e48b028\",\"license\":\"BUSL-1.1\"},\"contracts/protocols/vault/vaultT1/coreModule/main.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\nimport { IFluidOracle } from \\\"../../../../oracle/fluidOracle.sol\\\";\\n\\nimport { TickMath } from \\\"../../../../libraries/tickMath.sol\\\";\\nimport { BigMathMinified } from \\\"../../../../libraries/bigMathMinified.sol\\\";\\nimport { BigMathVault } from \\\"../../../../libraries/bigMathVault.sol\\\";\\nimport { LiquidityCalcs } from \\\"../../../../libraries/liquidityCalcs.sol\\\";\\nimport { SafeTransfer } from \\\"../../../../libraries/safeTransfer.sol\\\";\\n\\nimport { Helpers } from \\\"./helpers.sol\\\";\\nimport { LiquiditySlotsLink } from \\\"../../../../libraries/liquiditySlotsLink.sol\\\";\\n\\nimport { ErrorTypes } from \\\"../../errorTypes.sol\\\";\\n\\n/// @notice Fluid \\\"VaultT1\\\" (Vault Type 1). Fluid vault protocol main contract.\\n///         Fluid Vault protocol is a borrow / lending protocol, allowing users to create collateral / borrow positions.\\n///         All funds are deposited into / borrowed from Fluid Liquidity layer.\\n///         Positions are represented through NFTs minted by the VaultFactory.\\n///         Deployed by \\\"VaultFactory\\\" and linked together with VaultT1 AdminModule `ADMIN_IMPLEMENTATION` and\\n///         FluidVaultT1Secondary (main2.sol) `SECONDARY_IMPLEMENTATION`.\\n///         AdminModule & FluidVaultT1Secondary methods are delegateCalled, if the msg.sender has the required authorization.\\n///         This contract links to an Oracle, which is used to assess collateral / debt value. Oracles implement the\\n///         \\\"FluidOracle\\\" base contract and return the price in 1e27 precision.\\n/// @dev    For view methods / accessing data, use the \\\"VaultResolver\\\" periphery contract.\\ncontract FluidVaultT1 is Helpers {\\n    using BigMathMinified for uint256;\\n    using BigMathVault for uint256;\\n\\n    /// @dev Single function which handles supply, withdraw, borrow & payback\\n    /// @param nftId_ NFT ID for interaction. If 0 then create new NFT/position.\\n    /// @param newCol_ new collateral. If positive then deposit, if negative then withdraw, if 0 then do nohing\\n    /// @param newDebt_ new debt. If positive then borrow, if negative then payback, if 0 then do nohing\\n    /// @param to_ address where withdraw or borrow should go. If address(0) then msg.sender\\n    /// @return nftId_ if 0 then this returns the newly created NFT Id else returns the same NFT ID\\n    /// @return newCol_ final supply amount. Mainly if max withdraw using type(int).min then this is useful to get perfect amount else remain same as newCol_\\n    /// @return newDebt_ final borrow amount. Mainly if max payback using type(int).min then this is useful to get perfect amount else remain same as newDebt_\\n    function operate(\\n        uint256 nftId_, // if 0 then new position\\n        int256 newCol_, // if negative then withdraw\\n        int256 newDebt_, // if negative then payback\\n        address to_ // address at which the borrow & withdraw amount should go to. If address(0) then it'll go to msg.sender\\n    )\\n        public\\n        payable\\n        returns (\\n            uint256, // nftId_\\n            int256, // final supply amount. if - then withdraw\\n            int256 // final borrow amount. if - then payback\\n        )\\n    {\\n        uint256 vaultVariables_ = vaultVariables;\\n        // re-entrancy check\\n        if (vaultVariables_ & 1 == 0) {\\n            // Updating on storage\\n            vaultVariables = vaultVariables_ | 1;\\n        } else {\\n            revert FluidVaultError(ErrorTypes.VaultT1__AlreadyEntered);\\n        }\\n\\n        if (\\n            (newCol_ == 0 && newDebt_ == 0) ||\\n            // withdrawal or deposit cannot be too small\\n            ((newCol_ != 0) && (newCol_ > -10000 && newCol_ < 10000)) ||\\n            // borrow or payback cannot be too small\\n            ((newDebt_ != 0) && (newDebt_ > -10000 && newDebt_ < 10000))\\n        ) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__InvalidOperateAmount);\\n        }\\n\\n        // Check msg.value aligns with input amounts if supply or borrow token is native token.\\n        // Note that it's not possible for a vault to have both supply token and borrow token as native token.\\n        if (SUPPLY_TOKEN == NATIVE_TOKEN && newCol_ > 0) {\\n            if (uint(newCol_) != msg.value) {\\n                revert FluidVaultError(ErrorTypes.VaultT1__InvalidMsgValueOperate);\\n            }\\n        } else if (msg.value > 0) {\\n            if (!(BORROW_TOKEN == NATIVE_TOKEN && newDebt_ < 0)) {\\n                // msg.value sent along for withdraw, borrow, or non-native token operations\\n                revert FluidVaultError(ErrorTypes.VaultT1__InvalidMsgValueOperate);\\n            }\\n        }\\n\\n        OperateMemoryVars memory o_;\\n        // Temporary variables used as helpers at many places\\n        uint256 temp_;\\n        uint256 temp2_;\\n        int256 temp3_;\\n\\n        o_.vaultVariables2 = vaultVariables2;\\n\\n        temp_ = (vaultVariables_ >> 2) & X20;\\n        unchecked {\\n            o_.topTick = (temp_ == 0) ? type(int).min : ((temp_ & 1) == 1)\\n                ? int((temp_ >> 1) & X19)\\n                : -int((temp_ >> 1) & X19);\\n        }\\n\\n        {\\n            // Fetching user's position\\n            if (nftId_ == 0) {\\n                // creating new position.\\n                o_.tick = type(int).min;\\n                // minting new NFT vault for user.\\n                nftId_ = VAULT_FACTORY.mint(VAULT_ID, msg.sender);\\n                // Adding 1 in total positions. Total positions cannot exceed 32bits as NFT minting checks for that\\n                unchecked {\\n                    vaultVariables_ = vaultVariables_ + (1 << 210);\\n                }\\n            } else {\\n                // Updating existing position\\n\\n                // checking owner only in case of withdraw or borrow\\n                if ((newCol_ < 0 || newDebt_ > 0) && (VAULT_FACTORY.ownerOf(nftId_) != msg.sender)) {\\n                    revert FluidVaultError(ErrorTypes.VaultT1__NotAnOwner);\\n                }\\n\\n                // temp_ => user's position data\\n                temp_ = positionData[nftId_];\\n\\n                if (temp_ == 0) {\\n                    revert FluidVaultError(ErrorTypes.VaultT1__NftNotOfThisVault);\\n                }\\n                // temp2_ => user's supply amount\\n                temp2_ = (temp_ >> 45) & X64;\\n                // Converting big number into normal number\\n                o_.colRaw = (temp2_ >> 8) << (temp2_ & X8);\\n                // temp2_ => user's  dust debt amount\\n                temp2_ = (temp_ >> 109) & X64;\\n                // Converting big number into normal number\\n                o_.dustDebtRaw = (temp2_ >> 8) << (temp2_ & X8);\\n\\n                // 1 is supply & 0 is borrow\\n                if (temp_ & 1 == 1) {\\n                    // only supply position (has no debt)\\n                    o_.tick = type(int).min;\\n                } else {\\n                    // borrow position (has collateral & debt)\\n                    unchecked {\\n                        o_.tick = temp_ & 2 == 2 ? int((temp_ >> 2) & X19) : -int((temp_ >> 2) & X19);\\n                    }\\n                    o_.tickId = (temp_ >> 21) & X24;\\n                }\\n            }\\n        }\\n\\n        // Get latest updated Position's debt & supply (if position is with debt -> not new / supply position)\\n        if (o_.tick > type(int).min) {\\n            // if entering this if statement then temp_ here will always be user's position data\\n            // extracting collateral exponent\\n            temp_ = (temp_ >> 45) & X8;\\n            // if exponent is > 0 then rounding up the collateral just for calculating debt\\n            unchecked {\\n                temp_ = temp_ == 0 ? (o_.colRaw + 1) : o_.colRaw + (1 << temp_);\\n            }\\n            // fetch current debt\\n            o_.debtRaw = ((TickMath.getRatioAtTick(int24(o_.tick)) * temp_) >> 96) + 1;\\n\\n            // Tick data from user's tick\\n            temp_ = tickData[o_.tick];\\n\\n            // Checking if tick is liquidated (first bit 1) OR if the total IDs of tick is greater than user's tick ID\\n            if (((temp_ & 1) == 1) || (((temp_ >> 1) & X24) > o_.tickId)) {\\n                // User got liquidated\\n                (\\n                    // returns the position of the user if the user got liquidated.\\n                    o_.tick,\\n                    o_.debtRaw,\\n                    o_.colRaw,\\n                    temp2_, // final branchId from liquidation where position exist right now\\n                    o_.branchData\\n                ) = fetchLatestPosition(o_.tick, o_.tickId, o_.debtRaw, temp_);\\n\\n                if (o_.debtRaw > o_.dustDebtRaw) {\\n                    // temp_ => branch's Debt\\n                    temp_ = (o_.branchData >> 52) & X64;\\n                    temp_ = (temp_ >> 8) << (temp_ & X8);\\n\\n                    // o_.debtRaw should always be < branch's Debt (temp_).\\n                    // Taking margin (0.01%) in fetchLatestPosition to make sure it's always less\\n                    temp_ -= o_.debtRaw;\\n                    if (temp_ < 100) {\\n                        // explicitly making sure that branch debt/liquidity doesn't get super low.\\n                        temp_ = 100;\\n                    }\\n                    // Inserting updated branch's debt\\n                    branchData[temp2_] =\\n                        (o_.branchData & 0xfffffffffffffffffffffffffffffffffff0000000000000000fffffffffffff) |\\n                        (temp_.toBigNumber(56, 8, BigMathMinified.ROUND_UP) << 52);\\n\\n                    unchecked {\\n                        // Converted positionRawDebt_ in net position debt\\n                        o_.debtRaw -= o_.dustDebtRaw;\\n                    }\\n                } else {\\n                    // Liquidated 100% or almost 100%\\n                    // absorbing dust debt\\n                    absorbedDustDebt = absorbedDustDebt + o_.dustDebtRaw - o_.debtRaw;\\n                    o_.debtRaw = 0;\\n                    o_.colRaw = 0;\\n                }\\n            } else {\\n                // User didn't got liquidated\\n                // Removing user's debt from tick data\\n                // temp2_ => debt in tick\\n                temp2_ = (temp_ >> 25) & X64;\\n                // below require can fail when a user liquidity is extremely low (talking about way less than even $1)\\n                // adding require meaning this vault user won't be able to interact unless someone makes the liquidity in tick as non 0.\\n                // reason of adding is the tick has already removed from everywhere. Can removing it again break something? Better to simply remove that case entirely\\n                if (temp2_ == 0) {\\n                    revert FluidVaultError(ErrorTypes.VaultT1__TickIsEmpty);\\n                }\\n                // Converting big number into normal number\\n                temp2_ = (temp2_ >> 8) << (temp2_ & X8);\\n                // debtInTick (temp2_) < debtToRemove (o_.debtRaw) that means minor precision error. Hence make the debtInTick as 0.\\n                // The precision error can be caused with Bigmath library limiting the precision to 2**56.\\n                unchecked {\\n                    temp2_ = o_.debtRaw < temp2_ ? temp2_ - o_.debtRaw : 0;\\n                }\\n\\n                if (temp2_ < 10000) {\\n                    temp2_ = 0;\\n                    // if debt becomes 0 then remove from tick has debt\\n\\n                    if (o_.tick == o_.topTick) {\\n                        // if tick is top tick then current top tick is perfect tick -> fetch & set new top tick\\n\\n                        // Updating new top tick in vaultVariables_ and topTick_\\n                        (vaultVariables_, o_.topTick) = _setNewTopTick(o_.topTick, vaultVariables_);\\n                    }\\n\\n                    // Removing from tickHasDebt\\n                    _updateTickHasDebt(o_.tick, false);\\n                }\\n\\n                tickData[o_.tick] = (temp_ & X25) | (temp2_.toBigNumber(56, 8, BigMathMinified.ROUND_DOWN) << 25);\\n\\n                // Converted positionRawDebt_ in net position debt\\n                o_.debtRaw -= o_.dustDebtRaw;\\n            }\\n            o_.dustDebtRaw = 0;\\n        }\\n\\n        // Setting the current tick into old tick as the position tick is going to change now.\\n        o_.oldTick = o_.tick;\\n        o_.oldColRaw = o_.colRaw;\\n        o_.oldNetDebtRaw = o_.debtRaw;\\n\\n        {\\n            (o_.liquidityExPrice, , o_.supplyExPrice, o_.borrowExPrice) = updateExchangePrices(o_.vaultVariables2);\\n\\n            {\\n                // supply or withdraw\\n                if (newCol_ > 0) {\\n                    // supply new col, rounding down\\n                    o_.colRaw += (uint256(newCol_) * EXCHANGE_PRICES_PRECISION) / o_.supplyExPrice;\\n                    // final user's collateral should not be above 2**128 bits\\n                    if (o_.colRaw > X128) {\\n                        revert FluidVaultError(ErrorTypes.VaultT1__UserCollateralDebtExceed);\\n                    }\\n                } else if (newCol_ < 0) {\\n                    // if withdraw equals type(int).min then max withdraw\\n                    if (newCol_ > type(int128).min) {\\n                        // partial withdraw, rounding up removing extra wei from collateral\\n                        temp3_ = ((newCol_ * int(EXCHANGE_PRICES_PRECISION)) / int256(o_.supplyExPrice)) - 1;\\n                        unchecked {\\n                            if (uint256(-temp3_) > o_.colRaw) {\\n                                revert FluidVaultError(ErrorTypes.VaultT1__ExcessCollateralWithdrawal);\\n                            }\\n                            o_.colRaw -= uint256(-temp3_);\\n                        }\\n                    } else if (newCol_ == type(int).min) {\\n                        // max withdraw, rounding up:\\n                        // adding +1 to negative withdrawAmount newCol_ for safe rounding (reducing withdraw)\\n                        newCol_ = -(int256((o_.colRaw * o_.supplyExPrice) / EXCHANGE_PRICES_PRECISION)) + 1;\\n                        o_.colRaw = 0;\\n                    } else {\\n                        revert FluidVaultError(ErrorTypes.VaultT1__UserCollateralDebtExceed);\\n                    }\\n                }\\n            }\\n            {\\n                // borrow or payback\\n                if (newDebt_ > 0) {\\n                    // borrow new debt, rounding up adding extra wei in debt\\n                    temp_ = ((uint(newDebt_) * EXCHANGE_PRICES_PRECISION) / o_.borrowExPrice) + 1;\\n                    // if borrow fee is 0 then it'll become temp_ + 0.\\n                    // Only adding fee in o_.debtRaw and not in newDebt_ as newDebt_ is debt that needs to be borrowed from Liquidity\\n                    // as we have added fee in debtRaw hence it will get added in user's position & vault's total borrow.\\n                    // It can be collected with rebalance function.\\n                    o_.debtRaw += temp_ + (temp_ * ((o_.vaultVariables2 >> 82) & X10)) / 10000;\\n                    // final user's debt should not be above 2**128 bits\\n                    if (o_.debtRaw > X128) {\\n                        revert FluidVaultError(ErrorTypes.VaultT1__UserCollateralDebtExceed);\\n                    }\\n                } else if (newDebt_ < 0) {\\n                    // if payback equals type(int).min then max payback\\n                    if (newDebt_ > type(int128).min) {\\n                        // partial payback.\\n                        // temp3_ => newDebt_ in raw terms, safe rounding up negative amount to rounding reduce payback\\n                        temp3_ = (newDebt_ * int256(EXCHANGE_PRICES_PRECISION)) / int256(o_.borrowExPrice) + 1;\\n                        unchecked {\\n                            temp3_ = -temp3_;\\n                            if (uint256(temp3_) > o_.debtRaw) {\\n                                revert FluidVaultError(ErrorTypes.VaultT1__ExcessDebtPayback);\\n                            }\\n                            o_.debtRaw -= uint256(temp3_);\\n                        }\\n                    } else if (newDebt_ == type(int).min) {\\n                        // max payback, rounding up amount that will be transferred in to pay back full debt:\\n                        // subtracting -1 of negative debtAmount newDebt_ for safe rounding (increasing payback)\\n                        newDebt_ = -(int256((o_.debtRaw * o_.borrowExPrice) / EXCHANGE_PRICES_PRECISION)) - 1;\\n                        o_.debtRaw = 0;\\n                    } else {\\n                        revert FluidVaultError(ErrorTypes.VaultT1__UserCollateralDebtExceed);\\n                    }\\n                }\\n            }\\n        }\\n\\n        // if position has no collateral or debt and user sends type(int).min for withdraw and payback then this results in 0\\n        // there's is no issue if it stays 0 but better to throw here to avoid checking for potential issues if there could be\\n        if (newCol_ == 0 && newDebt_ == 0) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__InvalidOperateAmount);\\n        }\\n\\n        // Assign new tick\\n        if (o_.debtRaw > 0) {\\n            // updating tickHasDebt in the below function if required\\n            // o_.debtRaw here is updated to new debt raw incl. dust debt (not net debt)\\n            unchecked {\\n                (o_.tick, o_.tickId, o_.debtRaw, o_.dustDebtRaw) = _addDebtToTickWrite(\\n                    o_.colRaw,\\n                    ((o_.debtRaw * 1000000001) / 1000000000) + 1\\n                );\\n            }\\n\\n            if (newDebt_ < 0) {\\n                // anyone can payback debt of any position\\n                // hence, explicitly checking the debt should decrease\\n                if ((o_.debtRaw - o_.dustDebtRaw) > o_.oldNetDebtRaw) {\\n                    revert FluidVaultError(ErrorTypes.VaultT1__InvalidPaybackOrDeposit);\\n                }\\n            }\\n            if ((newCol_ > 0) && (newDebt_ == 0)) {\\n                // anyone can deposit collateral in any position\\n                // Hence, explicitly checking that new ratio should be less than old ratio\\n                if (\\n                    (((o_.debtRaw - o_.dustDebtRaw) * TickMath.ZERO_TICK_SCALED_RATIO) / o_.colRaw) >\\n                    ((o_.oldNetDebtRaw * TickMath.ZERO_TICK_SCALED_RATIO) / o_.oldColRaw)\\n                ) {\\n                    revert FluidVaultError(ErrorTypes.VaultT1__InvalidPaybackOrDeposit);\\n                }\\n            }\\n\\n            if (o_.tick >= o_.topTick) {\\n                // Updating topTick in storage\\n                // temp_ => tick to insert in vault variables\\n                unchecked {\\n                    temp_ = o_.tick < 0 ? uint(-o_.tick) << 1 : (uint(o_.tick) << 1) | 1;\\n                }\\n                if (vaultVariables_ & 2 == 0) {\\n                    // Current branch not liquidated. Hence, just update top tick\\n                    vaultVariables_ =\\n                        (vaultVariables_ & 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffc00000) |\\n                        (temp_ << 2);\\n                } else {\\n                    // Current branch liquidated\\n                    // Initialize a new branch\\n                    // temp2_ => totalBranchId_\\n                    unchecked {\\n                        temp2_ = ((vaultVariables_ >> 52) & X30) + 1; // would take 34 years to overflow if a new branch is created every second\\n                    }\\n                    // Connecting new active branch with current active branch which is now base branch\\n                    // Current top tick is now base branch's minima tick\\n                    branchData[temp2_] =\\n                        (((vaultVariables_ >> 22) & X30) << 166) | // current branch id set as base branch id\\n                        (((vaultVariables_ >> 2) & X20) << 196); // current top tick set as base branch minima tick\\n                    // Updating new vault variables in memory with new branch\\n                    vaultVariables_ =\\n                        (vaultVariables_ & 0xfffffffffffffffffffffffffffffffffffffffffffc00000000000000000000) |\\n                        (temp_ << 2) | // new top tick\\n                        (temp2_ << 22) | // new branch id\\n                        (temp2_ << 52); // total branch ids\\n                }\\n            }\\n        } else {\\n            // debtRaw_ remains 0 in this situation\\n            // This kind of position will not have any tick. Meaning it'll be a supply position.\\n            o_.tick = type(int).min;\\n        }\\n\\n        {\\n            if (newCol_ < 0 || newDebt_ > 0) {\\n                // withdraw or borrow\\n                if (to_ == address(0)) {\\n                    to_ = msg.sender;\\n                }\\n\\n                // if debt is greater than 0 & transaction includes borrow or withdraw (incl. combinations such as deposit + borrow etc.)\\n                // -> check collateral factor\\n                if (o_.debtRaw > 0) {\\n                    // Oracle returns price at 100% ratio.\\n                    // converting oracle 160 bits into oracle address\\n                    // temp_ => debt price w.r.t to col in 1e27\\n                    temp_ = IFluidOracle(address(uint160(o_.vaultVariables2 >> 96))).getExchangeRate();\\n                    // Note if price would come back as 0 `getTickAtRatio` will fail\\n\\n                    // Converting price in terms of raw amounts\\n                    temp_ = (temp_ * o_.supplyExPrice) / o_.borrowExPrice;\\n\\n                    unchecked {\\n                        // temp2_ => ratio at CF. CF is in 3 decimals. 900 = 90%\\n                        temp2_ = ((temp_ * ((o_.vaultVariables2 >> 32) & X10)) / 1000);\\n\\n                        // Price from oracle is in 1e27 decimals. Converting it into (1 << 96) decimals\\n                        temp2_ = (temp2_ < 1e45)\\n                            ? ((temp2_ * TickMath.ZERO_TICK_SCALED_RATIO) / 1e27)\\n                            : (temp2_ / 1e27) * TickMath.ZERO_TICK_SCALED_RATIO;\\n                    }\\n\\n                    // temp3_ => tickAtCF_\\n                    (temp3_, ) = TickMath.getTickAtRatio(temp2_);\\n                    if (o_.tick > temp3_) {\\n                        unchecked {\\n                            // calc for net debt can be unchecked as o_.dustDebtRaw can not be > o_.debtRaw:\\n                            // o_.dustDebtRaw is the result of o_.debtRaw - x where x > 0 see _addDebtToTickWrite()\\n                            if (\\n                                o_.oldTick <= o_.tick ||\\n                                (o_.debtRaw - o_.dustDebtRaw) > (((o_.oldNetDebtRaw * 1000000001) / 1000000000) + 1)\\n                            ) {\\n                                // Above CF, user should only be allowed to reduce ratio either by paying debt or by depositing more collateral\\n                                // Not comparing collateral as user can potentially use safe/deleverage to reduce tick & debt.\\n                                // On use of safe/deleverage, collateral will decrease but debt will decrease as well making the overall position safer.\\n                                revert FluidVaultError(ErrorTypes.VaultT1__PositionAboveCF);\\n                            }\\n                        }\\n                    }\\n                }\\n            }\\n        }\\n\\n        {\\n            // Updating user's new position on storage\\n            // temp_ => tick to insert as user position tick\\n            if (o_.tick > type(int).min) {\\n                unchecked {\\n                    temp_ = o_.tick < 0 ? (uint(-o_.tick) << 1) : ((uint(o_.tick) << 1) | 1);\\n                }\\n            } else {\\n                // if positionTick_ = type(int).min OR positionRawDebt_ == 0 then that means it's only supply position\\n                // (for case of positionRawDebt_ == 0, tick is set to type(int).min further up)\\n                temp_ = 0;\\n            }\\n\\n            positionData[nftId_] =\\n                ((temp_ == 0) ? 1 : 0) | // setting if supply only position (1) or not (first bit)\\n                (temp_ << 1) |\\n                (o_.tickId << 21) |\\n                (o_.colRaw.toBigNumber(56, 8, BigMathMinified.ROUND_DOWN) << 45) |\\n                // dust debt is rounded down because user debt = debt - dustDebt. rounding up would mean we reduce user debt\\n                (o_.dustDebtRaw.toBigNumber(56, 8, BigMathMinified.ROUND_DOWN) << 109);\\n        }\\n\\n        // Withdrawal gap to make sure there's always liquidity for liquidation\\n        // For example if withdrawal allowance is 15% on liquidity then we can limit operate's withdrawal allowance to 10%\\n        // this will allow liquidate function to get extra 5% buffer for potential liquidations.\\n        if (newCol_ < 0) {\\n            // extracting withdrawal gap which is in 0.1% precision.\\n            temp_ = (o_.vaultVariables2 >> 62) & X10;\\n            if (temp_ > 0) {\\n                // fetching user's supply slot data\\n                o_.userSupplyLiquidityData = LIQUIDITY.readFromStorage(LIQUIDITY_USER_SUPPLY_SLOT);\\n\\n                // converting current user's supply from big number to normal\\n                temp2_ = (o_.userSupplyLiquidityData >> LiquiditySlotsLink.BITS_USER_SUPPLY_AMOUNT) & X64;\\n                temp2_ = (temp2_ >> 8) << (temp2_ & X8);\\n\\n                // fetching liquidity's withdrawal limit\\n                temp3_ = int(LiquidityCalcs.calcWithdrawalLimitBeforeOperate(o_.userSupplyLiquidityData, temp2_));\\n\\n                // max the number could go is vault's supply * 1000. Overflowing is almost impossible.\\n                unchecked {\\n                    // (liquidityUserSupply - withdrawalGap - liquidityWithdrawaLimit) should be less than user's withdrawal\\n                    if (\\n                        (temp3_ > 0) &&\\n                        (((int(temp2_ * (1000 - temp_)) / 1000)) - temp3_) <\\n                        (((-newCol_) * int(EXCHANGE_PRICES_PRECISION)) / int(o_.liquidityExPrice))\\n                    ) {\\n                        revert FluidVaultError(ErrorTypes.VaultT1__WithdrawMoreThanOperateLimit);\\n                    }\\n                }\\n            }\\n        }\\n\\n        {\\n            // execute actions at Liquidity: deposit & payback is first and then withdraw & borrow\\n            if (newCol_ > 0) {\\n                // deposit\\n                LIQUIDITY.operate{ value: SUPPLY_TOKEN == NATIVE_TOKEN ? msg.value : 0 }(\\n                    SUPPLY_TOKEN,\\n                    newCol_,\\n                    0,\\n                    address(0),\\n                    address(0),\\n                    abi.encode(msg.sender)\\n                );\\n            }\\n            if (newDebt_ < 0) {\\n                if (BORROW_TOKEN == NATIVE_TOKEN) {\\n                    unchecked {\\n                        temp_ = uint(-newDebt_);\\n                        if (msg.value > temp_) {\\n                            SafeTransfer.safeTransferNative(msg.sender, msg.value - temp_);\\n                        } else if (msg.value < temp_) {\\n                            revert FluidVaultError(ErrorTypes.VaultT1__InvalidMsgValueOperate);\\n                        }\\n                    }\\n                } else {\\n                    temp_ = 0;\\n                }\\n                // payback\\n                LIQUIDITY.operate{ value: temp_ }(\\n                    BORROW_TOKEN,\\n                    0,\\n                    newDebt_,\\n                    address(0),\\n                    address(0),\\n                    abi.encode(msg.sender)\\n                );\\n            }\\n            if (newCol_ < 0) {\\n                // withdraw\\n                LIQUIDITY.operate(SUPPLY_TOKEN, newCol_, 0, to_, address(0), new bytes(0));\\n            }\\n            if (newDebt_ > 0) {\\n                // borrow\\n                LIQUIDITY.operate(BORROW_TOKEN, 0, newDebt_, address(0), to_, new bytes(0));\\n            }\\n        }\\n\\n        {\\n            // Updating vault variables on storage\\n\\n            // Calculating new total collateral & total debt.\\n            temp_ = (vaultVariables_ >> 82) & X64;\\n            temp_ = ((temp_ >> 8) << (temp_ & X8)) + o_.colRaw - o_.oldColRaw;\\n            temp2_ = (vaultVariables_ >> 146) & X64;\\n            temp2_ = ((temp2_ >> 8) << (temp2_ & X8)) + (o_.debtRaw - o_.dustDebtRaw) - o_.oldNetDebtRaw;\\n            // Updating vault variables on storage. This will also reentrancy 0 back again\\n            // Converting total supply & total borrow in 64 bits (56 | 8) bignumber\\n            vaultVariables =\\n                (vaultVariables_ & 0xfffffffffffc00000000000000000000000000000003ffffffffffffffffffff) |\\n                (temp_.toBigNumber(56, 8, BigMathMinified.ROUND_DOWN) << 82) | // total supply\\n                (temp2_.toBigNumber(56, 8, BigMathMinified.ROUND_UP) << 146); // total borrow\\n        }\\n\\n        emit LogOperate(msg.sender, nftId_, newCol_, newDebt_, to_);\\n\\n        return (nftId_, newCol_, newDebt_);\\n    }\\n\\n    /// @dev allows to liquidate all bad debt of all users at once. Liquidator can also liquidate partially any amount they want.\\n    /// @param debtAmt_ total debt to liquidate (aka debt token to swap into collateral token)\\n    /// @param colPerUnitDebt_ minimum collateral token per unit of debt in 1e18 decimals\\n    /// @param to_ address at which collateral token should go to.\\n    ///            If dead address (0x000000000000000000000000000000000000dEaD) then reverts with custom error \\\"FluidLiquidateResult\\\"\\n    ///            returning the actual collateral and actual debt liquidated. Useful to find max liquidatable amounts via try / catch.\\n    /// @param absorb_ if true then liquidate from absorbed first\\n    /// @return actualDebtAmt_ if liquidator sends debtAmt_ more than debt remaining to liquidate then actualDebtAmt_ changes from debtAmt_ else remains same\\n    /// @return actualColAmt_ total liquidated collateral which liquidator will get\\n    function liquidate(\\n        uint256 debtAmt_,\\n        uint256 colPerUnitDebt_, // min collateral needed per unit of debt in 1e18\\n        address to_,\\n        bool absorb_\\n    ) public payable returns (uint actualDebtAmt_, uint actualColAmt_) {\\n        LiquidateMemoryVars memory memoryVars_;\\n\\n        uint vaultVariables_ = vaultVariables;\\n\\n        // ############# turning re-entrancy bit on #############\\n        if (vaultVariables_ & 1 == 0) {\\n            // Updating on storage\\n            vaultVariables = vaultVariables_ | 1;\\n        } else {\\n            revert FluidVaultError(ErrorTypes.VaultT1__AlreadyEntered);\\n        }\\n\\n        if (debtAmt_ < 10000 || debtAmt_ > X128) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__InvalidLiquidationAmt);\\n        }\\n\\n        if (BORROW_TOKEN == NATIVE_TOKEN) {\\n            if ((msg.value != debtAmt_) && (to_ != 0x000000000000000000000000000000000000dEaD)) {\\n                revert FluidVaultError(ErrorTypes.VaultT1__InvalidMsgValueLiquidate);\\n            }\\n        } else if (msg.value > 0) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__InvalidMsgValueLiquidate);\\n        }\\n\\n        memoryVars_.vaultVariables2 = vaultVariables2;\\n\\n        if (((vaultVariables_ >> 2) & X20) == 0) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__TopTickDoesNotExist);\\n        }\\n\\n        // Below are exchange prices of vaults\\n        (, , memoryVars_.supplyExPrice, memoryVars_.borrowExPrice) = updateExchangePrices(memoryVars_.vaultVariables2);\\n\\n        CurrentLiquidity memory currentData_;\\n        BranchData memory branch_;\\n        // Temporary holder variables, used many times for different small things\\n        uint temp_;\\n        uint temp2_;\\n\\n        {\\n            // ############# Setting current branch in memory #############\\n\\n            // Updating branch related data\\n            branch_.id = (vaultVariables_ >> 22) & X30;\\n            branch_.data = branchData[branch_.id];\\n            branch_.debtFactor = (branch_.data >> 116) & X50;\\n            if (branch_.debtFactor == 0) {\\n                // Initializing branch debt factor. 35 | 15 bit number. Where full 35 bits and 15th bit is occupied.\\n                // Making the total number as (2**35 - 1) << 2**14.\\n                // note: initial debt factor can be any number.\\n                branch_.debtFactor = ((X35 << 15) | (1 << 14));\\n            }\\n            // fetching base branch's minima tick. if 0 that means it's a master branch\\n            temp_ = (branch_.data >> 196) & X20;\\n            if (temp_ > 0) {\\n                unchecked {\\n                    branch_.minimaTick = (temp_ & 1) == 1 ? int256((temp_ >> 1) & X19) : -int256((temp_ >> 1) & X19);\\n                }\\n            } else {\\n                branch_.minimaTick = type(int).min;\\n            }\\n        }\\n\\n        // extracting top tick as top tick will be the current tick\\n        unchecked {\\n            currentData_.tick = (vaultVariables_ & 4) == 4\\n                ? int256((vaultVariables_ >> 3) & X19)\\n                : -int256((vaultVariables_ >> 3) & X19);\\n        }\\n        // setting up status if top tick is liquidated or not\\n        currentData_.tickStatus = vaultVariables_ & 2 == 0 ? 1 : 2;\\n        // Tick info is mainly used as a place holder to store temporary tick related data\\n        // (it can be current or ref using same memory variable)\\n        TickData memory tickInfo_;\\n        tickInfo_.tick = currentData_.tick;\\n\\n        {\\n            // ############# Oracle related stuff #############\\n            // Col price w.r.t debt. For example: 1 ETH = 1000 DAI\\n            // temp_ -> debtPerCol\\n            temp_ = IFluidOracle(address(uint160(memoryVars_.vaultVariables2 >> 96))).getExchangeRate(); // Price in 27 decimals\\n            // temp_ -> debtPerCol Converting in terms of raw amount\\n            temp_ = (temp_ * memoryVars_.supplyExPrice) / memoryVars_.borrowExPrice;\\n            // temp2_ -> Raw colPerDebt_ in 27 decimals\\n            temp2_ = 1e54 / temp_;\\n\\n            // temp2_ can never be > 1e54\\n            // Oracle price should never be > 1e54\\n            unchecked {\\n                // Liquidation penalty in 4 decimals (1e2 = 1%) (max: 10.23%) -> (vaultVariables2_ >> 72) & X10\\n                currentData_.colPerDebt = (temp2_ * (10000 + ((memoryVars_.vaultVariables2 >> 72) & X10))) / 10000;\\n\\n                // get liquidiation tick (tick at liquidation threshold ratio)\\n                // Liquidation threshold in 3 decimals (900 = 90%) -> (vaultVariables2_ >> 42) & X10\\n                // Dividing by 1e27 to convert temp_ into normal number\\n                temp_ = (temp_ < 1e45)\\n                    ? ((temp_ * TickMath.ZERO_TICK_SCALED_RATIO) / 1e27)\\n                    : ((temp_ / 1e27) * TickMath.ZERO_TICK_SCALED_RATIO);\\n                // temp2_ -> liquidationRatio_\\n                temp2_ = (temp_ * ((memoryVars_.vaultVariables2 >> 42) & X10)) / 1000;\\n            }\\n            (memoryVars_.liquidationTick, ) = TickMath.getTickAtRatio(temp2_);\\n\\n            // get liquidiation max limit tick (tick at liquidation max limit ratio)\\n            // Max limit in 3 decimals (900 = 90%) -> (vaultVariables2_ >> 52) & X10\\n            // temp2_ -> maxRatio_\\n            unchecked {\\n                temp2_ = (temp_ * ((memoryVars_.vaultVariables2 >> 52) & X10)) / 1000;\\n            }\\n            (memoryVars_.maxTick, ) = TickMath.getTickAtRatio(temp2_);\\n        }\\n\\n        // debtAmt_ should be less than 2**128 & EXCHANGE_PRICES_PRECISION is 1e12\\n        unchecked {\\n            currentData_.debtRemaining = (debtAmt_ * EXCHANGE_PRICES_PRECISION) / memoryVars_.borrowExPrice;\\n        }\\n\\n        if (absorb_) {\\n            temp_ = absorbedLiquidity;\\n            // temp2_ -> absorbed col\\n            temp2_ = (temp_ >> 128) & X128;\\n            // temp_ -> absorbed debt\\n            temp_ = temp_ & X128;\\n\\n            if (temp_ > currentData_.debtRemaining) {\\n                // Removing collateral in equal proportion as debt\\n                currentData_.totalColLiq = ((temp2_ * currentData_.debtRemaining) / temp_);\\n                temp2_ -= currentData_.totalColLiq;\\n                // Removing debt\\n                currentData_.totalDebtLiq = currentData_.debtRemaining;\\n                unchecked {\\n                    temp_ -= currentData_.debtRemaining;\\n                }\\n                currentData_.debtRemaining = 0;\\n\\n                // updating on storage\\n                absorbedLiquidity = temp_ | (temp2_ << 128);\\n            } else {\\n                // updating on storage\\n                absorbedLiquidity = 0;\\n                unchecked {\\n                    currentData_.debtRemaining -= temp_;\\n                }\\n                currentData_.totalDebtLiq = temp_;\\n                currentData_.totalColLiq = temp2_;\\n            }\\n        }\\n\\n        if (\\n            currentData_.tick > memoryVars_.liquidationTick && // current tick > liquidation tick\\n            currentData_.tick <= memoryVars_.maxTick // current tick <= max tick\\n        ) {\\n            if (currentData_.debtRemaining > 0) {\\n                // Stores liquidated debt & collateral in each loop\\n                uint debtLiquidated_;\\n                uint colLiquidated_;\\n                uint debtFactor_ = BigMathVault.TWO_POWER_64;\\n\\n                TickHasDebt memory tickHasDebt_;\\n                unchecked {\\n                    tickHasDebt_.mapId = (currentData_.tick < 0)\\n                        ? (((currentData_.tick + 1) / 256) - 1)\\n                        : (currentData_.tick / 256);\\n                }\\n\\n                tickInfo_.ratio = TickMath.getRatioAtTick(tickInfo_.tick);\\n\\n                if (currentData_.tickStatus == 1) {\\n                    // top tick is not liquidated. Hence it's a perfect tick.\\n                    currentData_.ratio = tickInfo_.ratio;\\n                    // if current tick in liquidation is a perfect tick then it is also the next tick that has debt.\\n                    tickHasDebt_.nextTick = currentData_.tick;\\n                } else {\\n                    // top tick is liquidated. Hence it has partials.\\n                    // next tick that has debt liquidity will have to be fetched from tickHasDebt\\n                    unchecked {\\n                        tickInfo_.ratioOneLess = (tickInfo_.ratio * 10000) / 10015;\\n                        tickInfo_.length = tickInfo_.ratio - tickInfo_.ratioOneLess;\\n                        tickInfo_.partials = (branch_.data >> 22) & X30;\\n                        currentData_.ratio = tickInfo_.ratioOneLess + ((tickInfo_.length * tickInfo_.partials) / X30);\\n                    }\\n                    if (\\n                        (memoryVars_.liquidationTick + 1) == tickInfo_.tick && \\n                        (tickInfo_.partials == 1)\\n                    ) {\\n                        if (to_ == 0x000000000000000000000000000000000000dEaD) {\\n                            // revert with liquidated amounts if to_ address is the dead address.\\n                            // this can be used in a resolver to find the max liquidatable amounts.\\n                            revert FluidLiquidateResult(0, 0);\\n                        }\\n                        revert FluidVaultError(ErrorTypes.VaultT1__InvalidLiquidation);\\n                    }\\n                }\\n\\n                while (true) {\\n                    if (currentData_.tickStatus == 1) {\\n                        // not liquidated -> Getting the debt from tick data itself\\n                        temp2_ = tickData[currentData_.tick];\\n                        // temp_ => tick debt\\n                        temp_ = (temp2_ >> 25) & X64;\\n                        // Converting big number into normal number\\n                        temp_ = (temp_ >> 8) << (temp_ & X8);\\n                        // Updating tickData on storage with removing debt & adding connection to branch\\n                        tickData[currentData_.tick] =\\n                            1 | // set tick as liquidated\\n                            (temp2_ & 0x1fffffe) | // set same total tick ids\\n                            (branch_.id << 26) | // branch id where this tick got liquidated\\n                            (branch_.debtFactor << 56);\\n                    } else {\\n                        // already liquidated -> Get the debt from branch data in big number\\n                        // temp_ => tick debt\\n                        temp_ = (branch_.data >> 52) & X64;\\n                        // Converting big number into normal number\\n                        temp_ = (temp_ >> 8) << (temp_ & X8);\\n                        // Branch is getting updated over the end\\n                    }\\n\\n                    // Adding new debt into active debt for liquidation\\n                    currentData_.debt += temp_;\\n\\n                    // Adding new col into active col for liquidation\\n                    // Ratio is in 2**96 decimals hence multiplying debt with 2**96 to get proper collateral\\n                    currentData_.col += (temp_ * TickMath.ZERO_TICK_SCALED_RATIO) / currentData_.ratio;\\n\\n                    if (\\n                        (tickHasDebt_.nextTick == currentData_.tick && currentData_.tickStatus == 1) ||\\n                        tickHasDebt_.tickHasDebt == 0\\n                    ) {\\n                        // Fetching next perfect tick with liquidity\\n                        // tickHasDebt_.tickHasDebt == 0 will only happen in the first while loop\\n                        // in the very first perfect tick liquidation it'll be 0\\n                        if (tickHasDebt_.tickHasDebt == 0) {\\n                            tickHasDebt_.tickHasDebt = tickHasDebt[tickHasDebt_.mapId];\\n                        }\\n\\n                        // in 1st loop tickStatus can be 2. Meaning not a perfect current tick\\n                        if (currentData_.tickStatus == 1) {\\n                            unchecked {\\n                                tickHasDebt_.bitsToRemove = uint(-currentData_.tick + (tickHasDebt_.mapId * 256 + 256));\\n                            }\\n                            // Removing current top tick from tickHasDebt\\n                            tickHasDebt_.tickHasDebt =\\n                                (tickHasDebt_.tickHasDebt << tickHasDebt_.bitsToRemove) >>\\n                                tickHasDebt_.bitsToRemove;\\n                            // Updating in storage if tickHasDebt becomes 0.\\n                            if (tickHasDebt_.tickHasDebt == 0) {\\n                                tickHasDebt[tickHasDebt_.mapId] = 0;\\n                            }\\n                        }\\n\\n                        // For last user remaining in vault there could be a lot of while loop.\\n                        // Chances of this to happen is extremely low (like ~0%)\\n                        while (true) {\\n                            if (tickHasDebt_.tickHasDebt > 0) {\\n                                unchecked {\\n                                    tickHasDebt_.nextTick =\\n                                        tickHasDebt_.mapId *\\n                                        256 +\\n                                        int(tickHasDebt_.tickHasDebt.mostSignificantBit()) -\\n                                        1;\\n                                }\\n                                break;\\n                            }\\n\\n                            // tickHasDebt_.tickHasDebt == 0. Checking if minimum tick of this mapID is less than liquidationTick_\\n                            // if true that means now the next tick is not needed as liquidation gets over minimum at liquidationTick_\\n                            unchecked {\\n                                if ((tickHasDebt_.mapId * 256) < memoryVars_.liquidationTick) {\\n                                    tickHasDebt_.nextTick = type(int).min;\\n                                    break;\\n                                }\\n\\n                                // Fetching next tick has debt by decreasing tickHasDebt_.mapId first\\n                                tickHasDebt_.tickHasDebt = tickHasDebt[--tickHasDebt_.mapId];\\n                            }\\n                        }\\n                    }\\n\\n                    // Fetching refTick. refTick is the biggest tick of these 3:\\n                    // 1. Next tick with liquidity (from tickHasDebt)\\n                    // 2. Minima tick of current branch\\n                    // 3. Liquidation threshold tick\\n                    {\\n                        // Setting currentData_.refTick & currentData_.refTickStatus\\n                        if (\\n                            branch_.minimaTick > tickHasDebt_.nextTick &&\\n                            branch_.minimaTick > memoryVars_.liquidationTick\\n                        ) {\\n                            // next tick will be of base branch (merge)\\n                            currentData_.refTick = branch_.minimaTick;\\n                            currentData_.refTickStatus = 2;\\n                        } else if (tickHasDebt_.nextTick > memoryVars_.liquidationTick) {\\n                            // next tick will be next tick from perfect tick\\n                            currentData_.refTick = tickHasDebt_.nextTick;\\n                            currentData_.refTickStatus = 1;\\n                        } else {\\n                            // next tick is threshold tick\\n                            currentData_.refTick = memoryVars_.liquidationTick;\\n                            currentData_.refTickStatus = 3; // leads to end of liquidation loop\\n                        }\\n                    }\\n\\n                    // using tickInfo variable again for ref tick as we don't have the need for it any more\\n                    tickInfo_.ratio = TickMath.getRatioAtTick(int24(currentData_.refTick));\\n                    if (currentData_.refTickStatus == 2) {\\n                        // merge current branch with base branch\\n                        unchecked {\\n                            tickInfo_.ratioOneLess = (tickInfo_.ratio * 10000) / 10015;\\n                            tickInfo_.length = tickInfo_.ratio - tickInfo_.ratioOneLess;\\n                            // Fetching base branch data to get the base branch's partial\\n                            branch_.baseBranchData = branchData[((branch_.data >> 166) & X30)];\\n                            tickInfo_.partials = (branch_.baseBranchData >> 22) & X30;\\n                            tickInfo_.currentRatio =\\n                                tickInfo_.ratioOneLess +\\n                                ((tickInfo_.length * tickInfo_.partials) / X30);\\n                            currentData_.refRatio = tickInfo_.currentRatio;\\n                        }\\n                    } else {\\n                        // refTickStatus can only be 1 (next tick from perfect tick) or 3 (liquidation threshold tick)\\n                        tickInfo_.currentRatio = tickInfo_.ratio;\\n                        currentData_.refRatio = tickInfo_.ratio;\\n                        tickInfo_.partials = X30;\\n                    }\\n\\n                    // Formula: (debt_ - x) / (col_ - (x * colPerDebt_)) = ratioEnd_\\n                    // x = ((ratioEnd_ * col) - debt_) / ((colPerDebt_ * ratioEnd_) - 1)\\n                    // x is debtToLiquidate_\\n                    // col_ = debt_ / ratioStart_ -> (currentData_.debt / currentData_.ratio)\\n                    // ratioEnd_ is currentData_.refRatio\\n                    //\\n                    // Calculation results of numerator & denominator is always negative\\n                    // which will cancel out to give positive output in the end so we can safely cast to uint.\\n                    // for nominator:\\n                    // ratioStart can only be >= ratioEnd so first part can only be reducing currentData_.debt leading to\\n                    // currentData_.debt reduced - currentData_.debt original * 1e27 -> can only be a negative number\\n                    // for denominator:\\n                    // currentData_.colPerDebt and currentData_.refRatio are inversely proportional to each other.\\n                    // the maximum value they can ever be is ~9.97e26 which is the 0.3% away from 100% because liquidation\\n                    // threshold + liquidation penalty can never be > 99.7%. This can also be verified by going back from\\n                    // min / max ratio values further up where we fetch oracle price etc.\\n                    // as optimization we can inverse nominator and denominator subtraction to directly get a positive number.\\n\\n                    debtLiquidated_ =\\n                        // nominator\\n                        ((currentData_.debt - (currentData_.refRatio * currentData_.debt) / currentData_.ratio) *\\n                            1e27) /\\n                        // denominator\\n                        (1e27 - ((currentData_.colPerDebt * currentData_.refRatio) / TickMath.ZERO_TICK_SCALED_RATIO));\\n\\n                    colLiquidated_ = (debtLiquidated_ * currentData_.colPerDebt) / 1e27;\\n\\n                    if (currentData_.debt == debtLiquidated_) {\\n                        debtLiquidated_ -= 1;\\n                    }\\n\\n                    if (debtLiquidated_ >= currentData_.debtRemaining || currentData_.refTickStatus == 3) {\\n                        // End of liquidation as full amount to liquidate or liquidation threshold tick has been reached;\\n\\n                        // Updating tickHasDebt on storage.\\n                        tickHasDebt[tickHasDebt_.mapId] = tickHasDebt_.tickHasDebt;\\n\\n                        if (debtLiquidated_ >= currentData_.debtRemaining) {\\n                            // Liquidation ended between currentTick & refTick.\\n                            // Not all of liquidatable debt is actually liquidated -> recalculate\\n                            debtLiquidated_ = currentData_.debtRemaining;\\n                            colLiquidated_ = (debtLiquidated_ * currentData_.colPerDebt) / 1e27;\\n                            // Liquidating to debt. temp_ => final ratio after liquidation\\n                            // liquidatable debt - debtLiquidated / liquidatable col - colLiquidated\\n                            temp_ =\\n                                ((currentData_.debt - debtLiquidated_) * TickMath.ZERO_TICK_SCALED_RATIO) /\\n                                (currentData_.col - colLiquidated_);\\n                            // Fetching tick of where liquidation ended\\n                            (tickInfo_.tick, tickInfo_.ratioOneLess) = TickMath.getTickAtRatio(temp_);\\n                            // Increasing tick by 1 as final ratio will probably be a partial\\n                            unchecked {\\n                                ++tickInfo_.tick;\\n                                tickInfo_.ratio = (tickInfo_.ratioOneLess * 10015) / 10000;\\n                                tickInfo_.length = tickInfo_.ratio - tickInfo_.ratioOneLess;\\n                                tickInfo_.partials = ((temp_ - tickInfo_.ratioOneLess) * X30) / tickInfo_.length;\\n\\n                                // Taking edge cases where partial comes as 0 or X30 meaning perfect tick.\\n                                // Hence, increasing or reducing it by 1 as liquidation tick cannot be perfect tick.\\n                                tickInfo_.partials = tickInfo_.partials == 0 ? 1 : tickInfo_.partials >= X30\\n                                    ? X30 - 1\\n                                    : tickInfo_.partials;\\n                            }\\n                        } else {\\n                            // End in liquidation threshold.\\n                            // finalRatio_ = currentData_.refRatio;\\n                            // Increasing liquidation threshold tick by 1 partial. With 1 partial it'll reach to the next tick.\\n                            // Ratio change will be negligible. Doing this as liquidation threshold tick can also be a perfect non-liquidated tick.\\n                            unchecked {\\n                                tickInfo_.tick = currentData_.refTick + 1;\\n                            }\\n                            // Making partial as 1 so it doesn't stay perfect tick\\n                            tickInfo_.partials = 1;\\n                            // length is not needed as only partials are written to storage\\n                        }\\n\\n                        // debtFactor = debtFactor * (liquidatableDebt - debtLiquidated) / liquidatableDebt\\n                        // -> debtFactor * leftOverDebt / liquidatableDebt\\n                        debtFactor_ = (debtFactor_ * (currentData_.debt - debtLiquidated_)) / currentData_.debt;\\n                        currentData_.totalDebtLiq += debtLiquidated_;\\n                        currentData_.debt -= debtLiquidated_; // currentData_.debt => leftOverDebt after debtLiquidated_\\n                        currentData_.totalColLiq += colLiquidated_;\\n                        currentData_.col -= colLiquidated_; // currentData_.col => leftOverCol after colLiquidated_\\n\\n                        // Updating branch's debt factor & write to storage as liquidation is over\\n                        branch_.debtFactor = branch_.debtFactor.mulDivBigNumber(debtFactor_);\\n\\n                        if (currentData_.debt < 100) {\\n                            // this can happen when someone tries to create a dust tick\\n                            revert FluidVaultError(ErrorTypes.VaultT1__BranchDebtTooLow);\\n                        }\\n\\n                        unchecked {\\n                            // Tick to insert\\n                            temp2_ = tickInfo_.tick < 0\\n                                ? (uint(-tickInfo_.tick) << 1)\\n                                : ((uint(tickInfo_.tick) << 1) | 1);\\n                        }\\n\\n                        // Updating Branch data with debt factor, debt, partials, minima tick & assigning is liquidated\\n                        branchData[branch_.id] =\\n                            ((branch_.data >> 166) << 166) |\\n                            1 | // set as liquidated\\n                            (temp2_ << 2) | // minima tick of branch\\n                            (tickInfo_.partials << 22) |\\n                            (currentData_.debt.toBigNumber(56, 8, BigMathMinified.ROUND_UP) << 52) | // branch debt\\n                            (branch_.debtFactor << 116);\\n\\n                        // Updating vault variables with current branch & tick\\n                        vaultVariables_ =\\n                            ((vaultVariables_ >> 52) << 52) |\\n                            2 | // set as liquidated\\n                            (temp2_ << 2) | // top tick\\n                            (branch_.id << 22);\\n                        break;\\n                    }\\n\\n                    unchecked {\\n                        // debtLiquidated_ >= currentData_.debtRemaining leads to loop break in if statement above\\n                        // so this can be unchecked\\n                        currentData_.debtRemaining -= debtLiquidated_;\\n                    }\\n\\n                    // debtFactor = debtFactor * (liquidatableDebt - debtLiquidated) / liquidatableDebt\\n                    // -> debtFactor * leftOverDebt / liquidatableDebt\\n                    debtFactor_ = (debtFactor_ * (currentData_.debt - debtLiquidated_)) / currentData_.debt;\\n                    currentData_.totalDebtLiq += debtLiquidated_;\\n                    currentData_.debt -= debtLiquidated_;\\n                    currentData_.totalColLiq += colLiquidated_;\\n                    currentData_.col -= colLiquidated_;\\n\\n                    // updating branch's debt factor\\n                    branch_.debtFactor = branch_.debtFactor.mulDivBigNumber(debtFactor_);\\n                    // Setting debt factor as 1 << 64 again\\n                    debtFactor_ = BigMathVault.TWO_POWER_64;\\n\\n                    if (currentData_.refTickStatus == 2) {\\n                        // ref tick is base branch's minima hence merging current branch to base branch\\n                        // and making base branch as current branch.\\n\\n                        // read base branch related data\\n                        temp_ = (branch_.data >> 166) & X30; // temp_ -> base branch id\\n                        temp2_ = branch_.baseBranchData;\\n                        {\\n                            uint newBranchDebtFactor_ = (temp2_ >> 116) & X50;\\n\\n                            // connectionFactor_ = baseBranchDebtFactor / currentBranchDebtFactor\\n                            uint connectionFactor_ = newBranchDebtFactor_.divBigNumber(branch_.debtFactor);\\n                            // Updating current branch in storage\\n                            branchData[branch_.id] =\\n                                ((branch_.data >> 166) << 166) | // deleting debt / partials / minima tick\\n                                2 | // setting as merged\\n                                (connectionFactor_ << 116); // set new connectionFactor\\n\\n                            // Storing base branch in memory\\n                            // Updating branch ID to base branch ID\\n                            branch_.id = temp_;\\n                            // Updating branch data with base branch data\\n                            branch_.data = temp2_;\\n                            // Remove next branch connection from base branch\\n                            branch_.debtFactor = newBranchDebtFactor_;\\n                            // temp_ => minima tick of base branch\\n                            temp_ = (temp2_ >> 196) & X20;\\n                            if (temp_ > 0) {\\n                                unchecked {\\n                                    branch_.minimaTick = (temp_ & 1) == 1\\n                                        ? int256((temp_ >> 1) & X19)\\n                                        : -int256((temp_ >> 1) & X19);\\n                                }\\n                            } else {\\n                                branch_.minimaTick = type(int).min;\\n                            }\\n                        }\\n                    }\\n\\n                    // Making refTick as currentTick\\n                    currentData_.tick = currentData_.refTick;\\n                    currentData_.tickStatus = currentData_.refTickStatus;\\n                    currentData_.ratio = currentData_.refRatio;\\n                }\\n            }\\n        }\\n\\n        // calculating net token amounts using exchange price\\n        actualDebtAmt_ = (currentData_.totalDebtLiq * memoryVars_.borrowExPrice) / EXCHANGE_PRICES_PRECISION;\\n        actualColAmt_ = (currentData_.totalColLiq * memoryVars_.supplyExPrice) / EXCHANGE_PRICES_PRECISION;\\n\\n        // Chances of this to happen are in few wei\\n        if (actualDebtAmt_ > debtAmt_) {\\n            // calc new actualColAmt_ via ratio.\\n            actualColAmt_ = actualColAmt_ * (debtAmt_ / actualDebtAmt_);\\n            actualDebtAmt_ = debtAmt_;\\n        }\\n\\n        if (((actualColAmt_ * 1e18) / actualDebtAmt_) < colPerUnitDebt_) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__ExcessSlippageLiquidation);\\n        }\\n\\n        if (to_ == 0x000000000000000000000000000000000000dEaD) {\\n            // revert with liquidated amounts if to_ address is the dead address.\\n            // this can be used in a resolver to find the max liquidatable amounts.\\n            revert FluidLiquidateResult(actualColAmt_, actualDebtAmt_);\\n        }\\n\\n        // payback at Liquidity\\n        if (BORROW_TOKEN == NATIVE_TOKEN) {\\n            temp_ = actualDebtAmt_;\\n            if (actualDebtAmt_ < msg.value) {\\n                unchecked {\\n                    // subtraction can be unchecked because of if check above\\n                    SafeTransfer.safeTransferNative(msg.sender, msg.value - actualDebtAmt_);\\n                }\\n            }\\n            // else if actualDebtAmt_ > msg.value not possible as actualDebtAmt_ can maximally be debtAmt_ and\\n            // msg.value == debtAmt_ is checked in the beginning of function.\\n        } else {\\n            temp_ = 0;\\n        }\\n        unchecked {\\n            // payback at liquidity\\n            LIQUIDITY.operate{ value: temp_ }(\\n                BORROW_TOKEN,\\n                0,\\n                -int(actualDebtAmt_),\\n                address(0),\\n                address(0),\\n                abi.encode(msg.sender)\\n            );\\n            // withdraw at liquidity\\n            LIQUIDITY.operate(SUPPLY_TOKEN, -int(actualColAmt_), 0, to_, address(0), new bytes(0));\\n        }\\n\\n        // Calculating new total collateral & total debt.\\n        // temp_ -> total supply\\n        temp_ = (vaultVariables_ >> 82) & X64;\\n        temp_ = ((temp_ >> 8) << (temp_ & X8)) - currentData_.totalColLiq;\\n        // temp2_ -> total borrow\\n        temp2_ = (vaultVariables_ >> 146) & X64;\\n        temp2_ = ((temp2_ >> 8) << (temp2_ & X8)) - currentData_.totalDebtLiq;\\n        // Updating vault variables on storage\\n        // Converting total supply & total borrow in 64 bits (56 | 8) bignumber\\n        vaultVariables =\\n            (vaultVariables_ & 0xfffffffffffc00000000000000000000000000000003ffffffffffffffffffff) |\\n            (temp_.toBigNumber(56, 8, BigMathMinified.ROUND_DOWN) << 82) | // total supply\\n            (temp2_.toBigNumber(56, 8, BigMathMinified.ROUND_UP) << 146); // total borrow\\n\\n        emit LogLiquidate(msg.sender, actualColAmt_, actualDebtAmt_, to_);\\n    }\\n\\n    /// @dev absorb function absorbs the bad debt if the bad debt is above max limit. The main use of it is\\n    /// if the bad debt didn't got liquidated in time maybe due to sudden price drop or bad debt was extremely small to liquidate\\n    /// and the bad debt goes above 100% ratio then there's no incentive for anyone to liquidate now\\n    /// hence absorb functions absorbs that bad debt to allow newer bad debt to liquidate seamlessly\\n    /// if absorbing were to happen after this it's on governance on how to deal with it\\n    /// although it can still be removed through liquidate via liquidator if the price goes back up and liquidation becomes beneficial\\n    /// upon absorbed user position gets 100% liquidated.\\n    function absorb() public {\\n        _spell(SECONDARY_IMPLEMENTATION, msg.data);\\n    }\\n\\n    /// @dev Checks total supply of vault's in Liquidity Layer & Vault contract and rebalance it accordingly\\n    /// if vault supply is more than Liquidity Layer then deposit difference through reserve/rebalance contract\\n    /// if vault supply is less than Liquidity Layer then withdraw difference to reserve/rebalance contract\\n    /// if vault borrow is more than Liquidity Layer then borrow difference to reserve/rebalance contract\\n    /// if vault borrow is less than Liquidity Layer then payback difference through reserve/rebalance contract\\n    function rebalance() external payable returns (int supplyAmt_, int borrowAmt_) {\\n        (supplyAmt_, borrowAmt_) = abi.decode(_spell(SECONDARY_IMPLEMENTATION, msg.data), (int, int));\\n    }\\n\\n    /// @dev liquidity callback for cheaper token transfers in case of deposit or payback.\\n    /// only callable by Liquidity during an operation.\\n    function liquidityCallback(address token_, uint amount_, bytes calldata data_) external {\\n        if (msg.sender != address(LIQUIDITY))\\n            revert FluidVaultError(ErrorTypes.VaultT1__InvalidLiquidityCallbackAddress);\\n        if (vaultVariables & 1 == 0) revert FluidVaultError(ErrorTypes.VaultT1__NotEntered);\\n\\n        SafeTransfer.safeTransferFrom(token_, abi.decode(data_, (address)), address(LIQUIDITY), amount_);\\n    }\\n\\n    constructor(ConstantViews memory constants_) Helpers(constants_) {\\n        // Note that vaults are deployed by VaultFactory so we somewhat trust the values being passed in\\n\\n        // Setting branch in vault.\\n        vaultVariables = (vaultVariables) | (1 << 22) | (1 << 52);\\n\\n        uint liqSupplyExchangePrice_ = (LIQUIDITY.readFromStorage(LIQUIDITY_SUPPLY_EXCHANGE_PRICE_SLOT) >>\\n            LiquiditySlotsLink.BITS_EXCHANGE_PRICES_SUPPLY_EXCHANGE_PRICE) & X64;\\n        uint liqBorrowExchangePrice_ = (LIQUIDITY.readFromStorage(LIQUIDITY_BORROW_EXCHANGE_PRICE_SLOT) >>\\n            LiquiditySlotsLink.BITS_EXCHANGE_PRICES_BORROW_EXCHANGE_PRICE) & X64;\\n\\n        if (\\n            liqSupplyExchangePrice_ < EXCHANGE_PRICES_PRECISION || liqBorrowExchangePrice_ < EXCHANGE_PRICES_PRECISION\\n        ) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__TokenNotInitialized);\\n        }\\n        // Updating initial rates in storage\\n        rates =\\n            liqSupplyExchangePrice_ |\\n            (liqBorrowExchangePrice_ << 64) |\\n            (EXCHANGE_PRICES_PRECISION << 128) |\\n            (EXCHANGE_PRICES_PRECISION << 192);\\n    }\\n\\n    fallback() external {\\n        if (!(VAULT_FACTORY.isGlobalAuth(msg.sender) || VAULT_FACTORY.isVaultAuth(msg.sender, address(this)))) {\\n            revert FluidVaultError(ErrorTypes.VaultT1__NotAnAuth);\\n        }\\n\\n        // Delegate the current call to `implementation`.\\n        // This does not return to its internall call site, it will return directly to the external caller.\\n        // solhint-disable-next-line no-inline-assembly\\n        _spell(ADMIN_IMPLEMENTATION, msg.data);\\n    }\\n\\n    function _spell(address target_, bytes memory data_) private returns (bytes memory response_) {\\n        assembly {\\n            let succeeded := delegatecall(gas(), target_, add(data_, 0x20), mload(data_), 0, 0)\\n            let size := returndatasize()\\n\\n            response_ := mload(0x40)\\n            mstore(0x40, add(response_, and(add(add(size, 0x20), 0x1f), not(0x1f))))\\n            mstore(response_, size)\\n            returndatacopy(add(response_, 0x20), 0, size)\\n\\n            switch iszero(succeeded)\\n            case 1 {\\n                // throw if delegatecall failed\\n                returndatacopy(0x00, 0x00, size)\\n                revert(0x00, size)\\n            }\\n        }\\n    }\\n}\\n\",\"keccak256\":\"0xa2c8a4739ec71dec484f0ba9879dc5b34b67ce57a2cc32d74eedbad84c8813a0\",\"license\":\"BUSL-1.1\"},\"contracts/protocols/vault/vaultT1/coreModule/structs.sol\":{\"content\":\"// SPDX-License-Identifier: BUSL-1.1\\npragma solidity 0.8.21;\\n\\ncontract Structs {\\n    // structs are used to mitigate Stack too deep errors\\n\\n    struct OperateMemoryVars {\\n        // ## User's position before update ##\\n        uint oldColRaw;\\n        uint oldNetDebtRaw; // total debt - dust debt\\n        int oldTick;\\n        // ## User's position after update ##\\n        uint colRaw;\\n        uint debtRaw; // total debt - dust debt\\n        uint dustDebtRaw;\\n        int tick;\\n        uint tickId;\\n        // others\\n        uint256 vaultVariables2;\\n        uint256 branchId;\\n        int256 topTick;\\n        uint liquidityExPrice;\\n        uint supplyExPrice;\\n        uint borrowExPrice;\\n        uint branchData;\\n        // user's supply slot data in liquidity\\n        uint userSupplyLiquidityData;\\n    }\\n\\n    struct BranchData {\\n        uint id;\\n        uint data;\\n        uint ratio;\\n        uint debtFactor;\\n        int minimaTick;\\n        uint baseBranchData;\\n    }\\n\\n    struct TickData {\\n        int tick;\\n        uint data;\\n        uint ratio;\\n        uint ratioOneLess;\\n        uint length;\\n        uint currentRatio; // current tick is ratio with partials.\\n        uint partials;\\n    }\\n\\n    // note: All the below token amounts are in raw form.\\n    struct CurrentLiquidity {\\n        uint256 debtRemaining; // Debt remaining to liquidate\\n        uint256 debt; // Current liquidatable debt before reaching next check point\\n        uint256 col; // Calculate using debt & ratioCurrent\\n        uint256 colPerDebt; // How much collateral to liquidate per unit of Debt\\n        uint256 totalDebtLiq; // Total debt liquidated till now\\n        uint256 totalColLiq; // Total collateral liquidated till now\\n        int tick; // Current tick to liquidate\\n        uint ratio; // Current ratio to liquidate\\n        uint tickStatus; // if 1 then it's a perfect tick, if 2 that means it's a liquidated tick\\n        int refTick; // ref tick to liquidate\\n        uint refRatio; // ratio at ref tick\\n        uint refTickStatus; // if 1 then it's a perfect tick, if 2 that means it's a liquidated tick, if 3 that means it's a liquidation threshold\\n    }\\n\\n    struct TickHasDebt {\\n        int tick; // current tick\\n        int nextTick; // next tick with liquidity\\n        int mapId; // mapping ID of tickHasDebt\\n        uint bitsToRemove; // liquidity to remove till tick_ so we can search for next tick\\n        uint tickHasDebt; // getting tickHasDebt_ from tickHasDebt[mapId_]\\n        uint mostSigBit; // most significant bit in tickHasDebt_ to get the next tick\\n    }\\n\\n    struct LiquidateMemoryVars {\\n        uint256 vaultVariables2;\\n        int liquidationTick;\\n        int maxTick;\\n        uint256 supplyExPrice;\\n        uint256 borrowExPrice;\\n    }\\n\\n    struct AbsorbMemoryVariables {\\n        uint256 supplyExPrice;\\n        uint256 borrowExPrice;\\n        uint256 debtAbsorbed;\\n        uint256 colAbsorbed;\\n        uint256 vaultVariables2;\\n        int256 startingTick;\\n        uint256 mostSigBit;\\n    }\\n\\n    struct ConstantViews {\\n        address liquidity;\\n        address factory;\\n        address adminImplementation;\\n        address secondaryImplementation;\\n        address supplyToken;\\n        address borrowToken;\\n        uint8 supplyDecimals;\\n        uint8 borrowDecimals;\\n        uint vaultId;\\n        bytes32 liquiditySupplyExchangePriceSlot;\\n        bytes32 liquidityBorrowExchangePriceSlot;\\n        bytes32 liquidityUserSupplySlot;\\n        bytes32 liquidityUserBorrowSlot;\\n    }\\n\\n    struct RebalanceMemoryVariables {\\n        uint256 liqSupplyExPrice;\\n        uint256 liqBorrowExPrice;\\n        uint256 vaultSupplyExPrice;\\n        uint256 vaultBorrowExPrice;\\n    }\\n}\\n\",\"keccak256\":\"0x0bc87f7f1e7c2fbcdb4b2d2f30eced71c39dd984dc52066c88712593e37ffc02\",\"license\":\"BUSL-1.1\"},\"solmate/src/utils/SSTORE2.sol\":{\"content\":\"// SPDX-License-Identifier: AGPL-3.0-only\\npragma solidity >=0.8.0;\\n\\n/// @notice Read and write to persistent storage at a fraction of the cost.\\n/// @author Solmate (https://github.com/transmissions11/solmate/blob/main/src/utils/SSTORE2.sol)\\n/// @author Modified from 0xSequence (https://github.com/0xSequence/sstore2/blob/master/contracts/SSTORE2.sol)\\nlibrary SSTORE2 {\\n    uint256 internal constant DATA_OFFSET = 1; // We skip the first byte as it's a STOP opcode to ensure the contract can't be called.\\n\\n    /*//////////////////////////////////////////////////////////////\\n                               WRITE LOGIC\\n    //////////////////////////////////////////////////////////////*/\\n\\n    function write(bytes memory data) internal returns (address pointer) {\\n        // Prefix the bytecode with a STOP opcode to ensure it cannot be called.\\n        bytes memory runtimeCode = abi.encodePacked(hex\\\"00\\\", data);\\n\\n        bytes memory creationCode = abi.encodePacked(\\n            //---------------------------------------------------------------------------------------------------------------//\\n            // Opcode  | Opcode + Arguments  | Description  | Stack View                                                     //\\n            //---------------------------------------------------------------------------------------------------------------//\\n            // 0x60    |  0x600B             | PUSH1 11     | codeOffset                                                     //\\n            // 0x59    |  0x59               | MSIZE        | 0 codeOffset                                                   //\\n            // 0x81    |  0x81               | DUP2         | codeOffset 0 codeOffset                                        //\\n            // 0x38    |  0x38               | CODESIZE     | codeSize codeOffset 0 codeOffset                               //\\n            // 0x03    |  0x03               | SUB          | (codeSize - codeOffset) 0 codeOffset                           //\\n            // 0x80    |  0x80               | DUP          | (codeSize - codeOffset) (codeSize - codeOffset) 0 codeOffset   //\\n            // 0x92    |  0x92               | SWAP3        | codeOffset (codeSize - codeOffset) 0 (codeSize - codeOffset)   //\\n            // 0x59    |  0x59               | MSIZE        | 0 codeOffset (codeSize - codeOffset) 0 (codeSize - codeOffset) //\\n            // 0x39    |  0x39               | CODECOPY     | 0 (codeSize - codeOffset)                                      //\\n            // 0xf3    |  0xf3               | RETURN       |                                                                //\\n            //---------------------------------------------------------------------------------------------------------------//\\n            hex\\\"60_0B_59_81_38_03_80_92_59_39_F3\\\", // Returns all code in the contract except for the first 11 (0B in hex) bytes.\\n            runtimeCode // The bytecode we want the contract to have after deployment. Capped at 1 byte less than the code size limit.\\n        );\\n\\n        /// @solidity memory-safe-assembly\\n        assembly {\\n            // Deploy a new contract with the generated creation code.\\n            // We start 32 bytes into the code to avoid copying the byte length.\\n            pointer := create(0, add(creationCode, 32), mload(creationCode))\\n        }\\n\\n        require(pointer != address(0), \\\"DEPLOYMENT_FAILED\\\");\\n    }\\n\\n    /*//////////////////////////////////////////////////////////////\\n                               READ LOGIC\\n    //////////////////////////////////////////////////////////////*/\\n\\n    function read(address pointer) internal view returns (bytes memory) {\\n        return readBytecode(pointer, DATA_OFFSET, pointer.code.length - DATA_OFFSET);\\n    }\\n\\n    function read(address pointer, uint256 start) internal view returns (bytes memory) {\\n        start += DATA_OFFSET;\\n\\n        return readBytecode(pointer, start, pointer.code.length - start);\\n    }\\n\\n    function read(\\n        address pointer,\\n        uint256 start,\\n        uint256 end\\n    ) internal view returns (bytes memory) {\\n        start += DATA_OFFSET;\\n        end += DATA_OFFSET;\\n\\n        require(pointer.code.length >= end, \\\"OUT_OF_BOUNDS\\\");\\n\\n        return readBytecode(pointer, start, end - start);\\n    }\\n\\n    /*//////////////////////////////////////////////////////////////\\n                          INTERNAL HELPER LOGIC\\n    //////////////////////////////////////////////////////////////*/\\n\\n    function readBytecode(\\n        address pointer,\\n        uint256 start,\\n        uint256 size\\n    ) private view returns (bytes memory data) {\\n        /// @solidity memory-safe-assembly\\n        assembly {\\n            // Get a pointer to some free memory.\\n            data := mload(0x40)\\n\\n            // Update the free memory pointer to prevent overriding our data.\\n            // We use and(x, not(31)) as a cheaper equivalent to sub(x, mod(x, 32)).\\n            // Adding 31 to size and running the result through the logic above ensures\\n            // the memory pointer remains word-aligned, following the Solidity convention.\\n            mstore(0x40, add(data, and(add(add(size, 32), 31), not(31))))\\n\\n            // Store the size of the data in the first 32 byte chunk of free memory.\\n            mstore(data, size)\\n\\n            // Copy the code into memory right after the 32 bytes we used to store the size.\\n            extcodecopy(pointer, add(data, 32), start, size)\\n        }\\n    }\\n}\\n\",\"keccak256\":\"0xc5359c92365c550c418725fc534a538426ea8f6e7f6c06c0a9d66647d864469d\",\"license\":\"AGPL-3.0-only\"}},\"version\":1}",
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  "devdoc": {
    "events": {
      "VaultT1Deployed(address,uint256,address,address)": {
        "params": {
          "borrowToken": "The address of the borrow token.",
          "supplyToken": "The address of the supply token.",
          "vault": "The address of the newly deployed vault.",
          "vaultId": "The id of the newly deployed vault."
        }
      }
    },
    "kind": "dev",
    "methods": {
      "vaultT1(address,address)": {
        "params": {
          "borrowToken_": "The address of the borrow token.",
          "supplyToken_": "The address of the supply token."
        },
        "returns": {
          "vaultCreationBytecode_": " Returns the bytecode of the new vault to deploy."
        }
      }
    },
    "version": 1
  },
  "userdoc": {
    "errors": {
      "FluidLiquidateResult(uint256,uint256)": [
        {
          "notice": "used to simulate liquidation to find the maximum liquidatable amounts"
        }
      ]
    },
    "events": {
      "VaultT1Deployed(address,uint256,address,address)": {
        "notice": "Emitted when a new vaultT1 is deployed."
      }
    },
    "kind": "user",
    "methods": {
      "ADDRESS_THIS()": {
        "notice": "address of this contract"
      },
      "ADMIN_IMPLEMENTATION()": {
        "notice": "address of Admin implementation"
      },
      "LIQUIDITY()": {
        "notice": "address of liquidity contract"
      },
      "SECONDARY_IMPLEMENTATION()": {
        "notice": "address of Secondary implementation"
      },
      "VAULT_T1_CREATIONCODE_ADDRESS()": {
        "notice": "SSTORE2 pointer for the VaultT1 creation code. Stored externally to reduce factory bytecode"
      },
      "vaultT1(address,address)": {
        "notice": "Computes vaultT1 bytecode for the given supply token (`supplyToken_`) and borrow token (`borrowToken_`).                                 This will be called by the VaultFactory via .delegateCall"
      }
    },
    "version": 1
  },
  "storageLayout": {
    "storage": [],
    "types": null
  }
}