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Contract Source Code Verified (Exact Match)
Contract Name:
PayloadIGP47
Compiler Version
v0.8.21+commit.d9974bed
Optimization Enabled:
Yes with 200 runs
Other Settings:
paris EvmVersion
Contract Source Code (Solidity Standard Json-Input format)
pragma solidity ^0.8.21;
pragma experimental ABIEncoderV2;
import {LiquidityCalcs} from "../libraries/liquidityCalcs.sol";
import {LiquiditySlotsLink} from "../libraries/liquiditySlotsLink.sol";
interface IGovernorBravo {
function _acceptAdmin() external;
function _setVotingDelay(uint256 newVotingDelay) external;
function _setVotingPeriod(uint256 newVotingPeriod) external;
function _acceptAdminOnTimelock() external;
function _setImplementation(address implementation_) external;
function propose(
address[] memory targets,
uint256[] memory values,
string[] memory signatures,
bytes[] memory calldatas,
string memory description
) external returns (uint256);
function admin() external view returns (address);
function pendingAdmin() external view returns (address);
function timelock() external view returns (address);
function votingDelay() external view returns (uint256);
function votingPeriod() external view returns (uint256);
}
interface ITimelock {
function acceptAdmin() external;
function setDelay(uint256 delay_) external;
function setPendingAdmin(address pendingAdmin_) external;
function queueTransaction(
address target,
uint256 value,
string memory signature,
bytes memory data,
uint256 eta
) external returns (bytes32);
function executeTransaction(
address target,
uint256 value,
string memory signature,
bytes memory data,
uint256 eta
) external payable returns (bytes memory);
function pendingAdmin() external view returns (address);
function admin() external view returns (address);
function delay() external view returns (uint256);
}
interface AdminModuleStructs {
struct AddressBool {
address addr;
bool value;
}
struct AddressUint256 {
address addr;
uint256 value;
}
struct RateDataV1Params {
address token;
uint256 kink;
uint256 rateAtUtilizationZero;
uint256 rateAtUtilizationKink;
uint256 rateAtUtilizationMax;
}
struct RateDataV2Params {
address token;
uint256 kink1;
uint256 kink2;
uint256 rateAtUtilizationZero;
uint256 rateAtUtilizationKink1;
uint256 rateAtUtilizationKink2;
uint256 rateAtUtilizationMax;
}
struct TokenConfig {
address token;
uint256 fee;
uint256 threshold;
}
struct UserSupplyConfig {
address user;
address token;
uint8 mode;
uint256 expandPercent;
uint256 expandDuration;
uint256 baseWithdrawalLimit;
}
struct UserBorrowConfig {
address user;
address token;
uint8 mode;
uint256 expandPercent;
uint256 expandDuration;
uint256 baseDebtCeiling;
uint256 maxDebtCeiling;
}
}
interface IFluidLiquidityAdmin {
/// @notice adds/removes auths. Auths generally could be contracts which can have restricted actions defined on contract.
/// auths can be helpful in reducing governance overhead where it's not needed.
/// @param authsStatus_ array of structs setting allowed status for an address.
/// status true => add auth, false => remove auth
function updateAuths(
AdminModuleStructs.AddressBool[] calldata authsStatus_
) external;
/// @notice adds/removes guardians. Only callable by Governance.
/// @param guardiansStatus_ array of structs setting allowed status for an address.
/// status true => add guardian, false => remove guardian
function updateGuardians(
AdminModuleStructs.AddressBool[] calldata guardiansStatus_
) external;
/// @notice changes the revenue collector address (contract that is sent revenue). Only callable by Governance.
/// @param revenueCollector_ new revenue collector address
function updateRevenueCollector(address revenueCollector_) external;
/// @notice changes current status, e.g. for pausing or unpausing all user operations. Only callable by Auths.
/// @param newStatus_ new status
/// status = 2 -> pause, status = 1 -> resume.
function changeStatus(uint256 newStatus_) external;
/// @notice update tokens rate data version 1. Only callable by Auths.
/// @param tokensRateData_ array of RateDataV1Params with rate data to set for each token
function updateRateDataV1s(
AdminModuleStructs.RateDataV1Params[] calldata tokensRateData_
) external;
/// @notice update tokens rate data version 2. Only callable by Auths.
/// @param tokensRateData_ array of RateDataV2Params with rate data to set for each token
function updateRateDataV2s(
AdminModuleStructs.RateDataV2Params[] calldata tokensRateData_
) external;
/// @notice updates token configs: fee charge on borrowers interest & storage update utilization threshold.
/// Only callable by Auths.
/// @param tokenConfigs_ contains token address, fee & utilization threshold
function updateTokenConfigs(
AdminModuleStructs.TokenConfig[] calldata tokenConfigs_
) external;
/// @notice updates user classes: 0 is for new protocols, 1 is for established protocols.
/// Only callable by Auths.
/// @param userClasses_ struct array of uint256 value to assign for each user address
function updateUserClasses(
AdminModuleStructs.AddressUint256[] calldata userClasses_
) external;
/// @notice sets user supply configs per token basis. Eg: with interest or interest-free and automated limits.
/// Only callable by Auths.
/// @param userSupplyConfigs_ struct array containing user supply config, see `UserSupplyConfig` struct for more info
function updateUserSupplyConfigs(
AdminModuleStructs.UserSupplyConfig[] memory userSupplyConfigs_
) external;
/// @notice setting user borrow configs per token basis. Eg: with interest or interest-free and automated limits.
/// Only callable by Auths.
/// @param userBorrowConfigs_ struct array containing user borrow config, see `UserBorrowConfig` struct for more info
function updateUserBorrowConfigs(
AdminModuleStructs.UserBorrowConfig[] memory userBorrowConfigs_
) external;
/// @notice pause operations for a particular user in class 0 (class 1 users can't be paused by guardians).
/// Only callable by Guardians.
/// @param user_ address of user to pause operations for
/// @param supplyTokens_ token addresses to pause withdrawals for
/// @param borrowTokens_ token addresses to pause borrowings for
function pauseUser(
address user_,
address[] calldata supplyTokens_,
address[] calldata borrowTokens_
) external;
/// @notice unpause operations for a particular user in class 0 (class 1 users can't be paused by guardians).
/// Only callable by Guardians.
/// @param user_ address of user to unpause operations for
/// @param supplyTokens_ token addresses to unpause withdrawals for
/// @param borrowTokens_ token addresses to unpause borrowings for
function unpauseUser(
address user_,
address[] calldata supplyTokens_,
address[] calldata borrowTokens_
) external;
/// @notice collects revenue for tokens to configured revenueCollector address.
/// @param tokens_ array of tokens to collect revenue for
/// @dev Note that this can revert if token balance is < revenueAmount (utilization > 100%)
function collectRevenue(address[] calldata tokens_) external;
/// @notice gets the current updated exchange prices for n tokens and updates all prices, rates related data in storage.
/// @param tokens_ tokens to update exchange prices for
/// @return supplyExchangePrices_ new supply rates of overall system for each token
/// @return borrowExchangePrices_ new borrow rates of overall system for each token
function updateExchangePrices(
address[] calldata tokens_
)
external
returns (
uint256[] memory supplyExchangePrices_,
uint256[] memory borrowExchangePrices_
);
function readFromStorage(
bytes32 slot_
) external view returns (uint256 result_);
}
interface FluidVaultFactory {
/// @notice Sets an address as allowed vault deployment logic (`deploymentLogic_`) contract or not.
/// This function can only be called by the owner.
/// @param deploymentLogic_ The address of the vault deployment logic contract to be set.
/// @param allowed_ A boolean indicating whether the specified address is allowed to deploy new type of vault.
function setVaultDeploymentLogic(
address deploymentLogic_,
bool allowed_
) external;
/// @notice Sets an address (`vaultAuth_`) as allowed vault authorization or not for a specific vault (`vault_`).
/// This function can only be called by the owner.
/// @param vault_ The address of the vault for which the authorization is being set.
/// @param vaultAuth_ The address to be set as vault authorization.
/// @param allowed_ A boolean indicating whether the specified address is allowed to update the specific vault config.
function setVaultAuth(
address vault_,
address vaultAuth_,
bool allowed_
) external;
/// @notice Computes the address of a vault based on its given ID (`vaultId_`).
/// @param vaultId_ The ID of the vault.
/// @return vault_ Returns the computed address of the vault.
function getVaultAddress(
uint256 vaultId_
) external view returns (address vault_);
}
interface IFluidVaultT1 {
/// @notice updates the Vault oracle to `newOracle_`. Must implement the FluidOracle interface.
function updateOracle(address newOracle_) external;
/// @notice updates the all Vault core settings according to input params.
/// All input values are expected in 1e2 (1% = 100, 100% = 10_000).
function updateCoreSettings(
uint256 supplyRateMagnifier_,
uint256 borrowRateMagnifier_,
uint256 collateralFactor_,
uint256 liquidationThreshold_,
uint256 liquidationMaxLimit_,
uint256 withdrawGap_,
uint256 liquidationPenalty_,
uint256 borrowFee_
) external;
/// @notice updates the allowed rebalancer to `newRebalancer_`.
function updateRebalancer(address newRebalancer_) external;
/// @notice updates the supply rate magnifier to `supplyRateMagnifier_`. Input in 1e2 (1% = 100, 100% = 10_000).
function updateSupplyRateMagnifier(uint supplyRateMagnifier_) external;
/// @notice updates the borrow rate magnifier to `borrowRateMagnifier_`. Input in 1e2 (1% = 100, 100% = 10_000).
function updateBorrowRateMagnifier(uint borrowRateMagnifier_) external;
/// @notice updates the collateral factor to `collateralFactor_`. Input in 1e2 (1% = 100, 100% = 10_000).
function updateCollateralFactor(uint collateralFactor_) external;
/// @notice updates the liquidation threshold to `liquidationThreshold_`. Input in 1e2 (1% = 100, 100% = 10_000).
function updateLiquidationThreshold(uint liquidationThreshold_) external;
/// @notice updates the liquidation max limit to `liquidationMaxLimit_`. Input in 1e2 (1% = 100, 100% = 10_000).
function updateLiquidationMaxLimit(uint liquidationMaxLimit_) external;
/// @notice updates the withdrawal gap to `withdrawGap_`. Input in 1e2 (1% = 100, 100% = 10_000).
function updateWithdrawGap(uint withdrawGap_) external;
/// @notice updates the liquidation penalty to `liquidationPenalty_`. Input in 1e2 (1% = 100, 100% = 10_000).
function updateLiquidationPenalty(uint liquidationPenalty_) external;
/// @notice updates the borrow fee to `borrowFee_`. Input in 1e2 (1% = 100, 100% = 10_000).
function updateBorrowFee(uint borrowFee_) external;
}
interface IFluidReserveContract {
function isRebalancer(address user) external returns (bool);
function rebalanceFToken(address protocol_) external;
function rebalanceVault(address protocol_) external;
function transferFunds(address token_) external;
function getProtocolTokens(address protocol_) external;
function updateAuth(address auth_, bool isAuth_) external;
function updateRebalancer(address rebalancer_, bool isRebalancer_) external;
function approve(
address[] memory protocols_,
address[] memory tokens_,
uint256[] memory amounts_
) external;
function revoke(
address[] memory protocols_,
address[] memory tokens_
) external;
}
contract PayloadIGP47 {
uint256 public constant PROPOSAL_ID = 47;
address public constant PROPOSER =
0xA45f7bD6A5Ff45D31aaCE6bCD3d426D9328cea01;
address public constant PROPOSER_AVO_MULTISIG =
0x059a94a72451c0ae1Cc1cE4bf0Db52421Bbe8210;
address public constant PROPOSER_AVO_MULTISIG_2 =
0x9efdE135CA4832AbF0408c44c6f5f370eB0f35e8;
address public constant PROPOSER_AVO_MULTISIG_3 =
0x5C43AAC965ff230AC1cF63e924D0153291D78BaD;
IGovernorBravo public constant GOVERNOR =
IGovernorBravo(0x0204Cd037B2ec03605CFdFe482D8e257C765fA1B);
ITimelock public constant TIMELOCK =
ITimelock(0x2386DC45AdDed673317eF068992F19421B481F4c);
address public constant TEAM_MULTISIG =
0x4F6F977aCDD1177DCD81aB83074855EcB9C2D49e;
address public immutable ADDRESS_THIS;
IFluidLiquidityAdmin public constant LIQUIDITY =
IFluidLiquidityAdmin(0x52Aa899454998Be5b000Ad077a46Bbe360F4e497);
IFluidReserveContract public constant FLUID_RESERVE =
IFluidReserveContract(0x264786EF916af64a1DB19F513F24a3681734ce92);
FluidVaultFactory public constant VAULT_FACTORY =
FluidVaultFactory(0x324c5Dc1fC42c7a4D43d92df1eBA58a54d13Bf2d);
address internal constant ETH_ADDRESS =
0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE;
address internal constant wstETH_ADDRESS =
0x7f39C581F595B53c5cb19bD0b3f8dA6c935E2Ca0;
address internal constant weETH_ADDRESS =
0xCd5fE23C85820F7B72D0926FC9b05b43E359b7ee;
address internal constant USDC_ADDRESS =
0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48;
address internal constant USDT_ADDRESS =
0xdAC17F958D2ee523a2206206994597C13D831ec7;
address internal constant sUSDe_ADDRESS =
0x9D39A5DE30e57443BfF2A8307A4256c8797A3497;
address internal constant sUSDs_ADDRESS =
0xa3931d71877C0E7a3148CB7Eb4463524FEc27fbD;
address internal constant GHO_ADDRESS =
0x40D16FC0246aD3160Ccc09B8D0D3A2cD28aE6C2f;
address internal constant WBTC_ADDRESS =
0x2260FAC5E5542a773Aa44fBCfeDf7C193bc2C599;
address internal constant cbBTC_ADDRESS =
0xcbB7C0000aB88B473b1f5aFd9ef808440eed33Bf;
struct Dex {
address dex;
address tokenA;
address tokenB;
bool smartCollateral;
bool smartDebt;
uint256 baseWithdrawalLimitInUSD;
uint256 baseBorrowLimitInUSD;
uint256 maxBorrowLimitInUSD;
}
enum TYPE {
TYPE_2,
TYPE_3,
TYPE_4
}
struct Vault {
address vault;
TYPE vaultType;
address supplyToken;
address borrowToken;
}
constructor() {
ADDRESS_THIS = address(this);
}
function propose(string memory description) external {
require(
msg.sender == PROPOSER ||
msg.sender == TEAM_MULTISIG ||
address(this) == PROPOSER_AVO_MULTISIG ||
address(this) == PROPOSER_AVO_MULTISIG_2 ||
address(PROPOSER_AVO_MULTISIG_3) == PROPOSER_AVO_MULTISIG_3,
"msg.sender-not-allowed"
);
uint256 totalActions = 1;
address[] memory targets = new address[](totalActions);
uint256[] memory values = new uint256[](totalActions);
string[] memory signatures = new string[](totalActions);
bytes[] memory calldatas = new bytes[](totalActions);
// Action 1: call executePayload on timelock contract to execute payload related to Fluid and Lite
targets[0] = address(TIMELOCK);
values[0] = 0;
signatures[0] = "executePayload(address,string,bytes)";
calldatas[0] = abi.encode(ADDRESS_THIS, "execute()", abi.encode());
uint256 proposedId = GOVERNOR.propose(
targets,
values,
signatures,
calldatas,
description
);
require(proposedId == PROPOSAL_ID, "PROPOSAL_IS_NOT_SAME");
}
function execute() external {
require(address(this) == address(TIMELOCK), "not-valid-caller");
// Action 1: Set GHO token config and market rate curve on liquidity.
action1();
// Action 2: Set GHO based vaults limits.
action2();
}
function verifyProposal() external view {}
/**
* |
* | Proposal Payload Actions |
* |__________________________________
*/
/// @notice Action 1: Set GHO token config and market rate curve on liquidity.
function action1() internal {
{
AdminModuleStructs.RateDataV1Params[]
memory params_ = new AdminModuleStructs.RateDataV1Params[](1);
params_[0] = AdminModuleStructs.RateDataV1Params({
token: GHO_ADDRESS, // GHO
kink: 93 * 1e2, // 93%
rateAtUtilizationZero: 0, // 0%
rateAtUtilizationKink: 7.5 * 1e2, // 7.5%
rateAtUtilizationMax: 25 * 1e2 // 25%
});
LIQUIDITY.updateRateDataV1s(params_);
}
}
/// @notice Action 2: Set GHO based vaults limits.
function action2() internal {
VaultConfig memory vaultConfig = VaultConfig({
vaultId: 0,
supplyToken: address(0),
supplyMode: 1, // Mode 1
supplyExpandPercent: 25 * 1e2, // 25%
supplyExpandDuration: 12 hours, // 12 hours
supplyBaseLimitInUSD: 7_500_000, // $7.5M
supplyBaseLimit: 0,
borrowToken: GHO_ADDRESS,
borrowMode: 1, // Mode 1
borrowExpandPercent: 20 * 1e2, // 20%
borrowExpandDuration: 12 hours, // 12 hours
borrowBaseLimitInUSD: 7_500_000, // $7.5M
borrowBaseLimit: 0,
borrowMaxLimitInUSD: 20_000_000, // $20M
borrowMaxLimit: 0,
supplyRateMagnifier: 100 * 1e2, // 1x
borrowRateMagnifier: 100 * 1e2, // 1x
collateralFactor: 0,
liquidationThreshold: 0,
liquidationMaxLimit: 0,
withdrawGap: 0,
liquidationPenalty: 0,
borrowFee: 0, // 0%
oracle: address(0)
});
// Config ETH/GHO vault.
{
vaultConfig.vaultId = 54;
vaultConfig.supplyToken = ETH_ADDRESS;
vaultConfig.borrowToken = GHO_ADDRESS;
vaultConfig.collateralFactor = 85 * 1e2; // 85%
vaultConfig.liquidationThreshold = 90 * 1e2; // 90%
vaultConfig.liquidationMaxLimit = 93 * 1e2; // 93%
vaultConfig.withdrawGap = 5 * 1e2; // 5%
vaultConfig.liquidationPenalty = 2.5 * 1e2; // 2.5%
vaultConfig.oracle = address(
0x39f6447ca8Ac3c6aa841B4C0D1fFb5D4DDb0FdE7
);
address vault_ = configVault(vaultConfig);
require(vault_ != address(0), "vault-not-deployed");
}
// Config wstETH/GHO vault.
{
vaultConfig.vaultId = 55;
vaultConfig.supplyToken = wstETH_ADDRESS;
vaultConfig.borrowToken = GHO_ADDRESS;
vaultConfig.collateralFactor = 82 * 1e2; // 82%
vaultConfig.liquidationThreshold = 88 * 1e2; // 88%
vaultConfig.liquidationMaxLimit = 92.5 * 1e2; // 92.5%
vaultConfig.withdrawGap = 5 * 1e2; // 5%
vaultConfig.liquidationPenalty = 3 * 1e2; // 3%
vaultConfig.oracle = address(
0xbEeCb9e594D008194c438f9e7234e17926c5070f
);
address vault_ = configVault(vaultConfig);
require(vault_ != address(0), "vault-not-deployed");
}
// Config sUSDe/GHO vault.
{
vaultConfig.vaultId = 56;
vaultConfig.supplyToken = sUSDe_ADDRESS;
vaultConfig.borrowToken = GHO_ADDRESS;
vaultConfig.collateralFactor = 88 * 1e2; // 88%
vaultConfig.liquidationThreshold = 90 * 1e2; // 90%
vaultConfig.liquidationMaxLimit = 95 * 1e2; // 95%
vaultConfig.withdrawGap = 5 * 1e2; // 5%
vaultConfig.liquidationPenalty = 2 * 1e2; // 2%
vaultConfig.oracle = address(
0x887d0aFb83949dd2d379e55E122c3c234D68F8BF
);
address vault_ = configVault(vaultConfig);
require(vault_ != address(0), "vault-not-deployed");
}
// Config weETH/GHO vault.
{
vaultConfig.vaultId = 57;
vaultConfig.supplyToken = weETH_ADDRESS;
vaultConfig.borrowToken = GHO_ADDRESS;
vaultConfig.collateralFactor = 77 * 1e2; // 77%
vaultConfig.liquidationThreshold = 82 * 1e2; // 82%
vaultConfig.liquidationMaxLimit = 90 * 1e2; // 90%
vaultConfig.withdrawGap = 5 * 1e2; // 5%
vaultConfig.liquidationPenalty = 3 * 1e2; // 3%
vaultConfig.oracle = address(
0x8d675657712C3621Fb5Ea57E6fE83F6799224C98
);
address vault_ = configVault(vaultConfig);
require(vault_ != address(0), "vault-not-deployed");
}
// Config sUSDs/GHO vault.
{
vaultConfig.vaultId = 58;
vaultConfig.supplyToken = sUSDs_ADDRESS;
vaultConfig.borrowToken = GHO_ADDRESS;
vaultConfig.collateralFactor = 90 * 1e2; // 90%
vaultConfig.liquidationThreshold = 92 * 1e2; // 92%
vaultConfig.liquidationMaxLimit = 95 * 1e2; // 95%
vaultConfig.withdrawGap = 5 * 1e2; // 5%
vaultConfig.liquidationPenalty = 2 * 1e2; // 2%
vaultConfig.oracle = address(
0xCac98B078aC63432d77dfd4DCFDB39D3033C9D11
);
address vault_ = configVault(vaultConfig);
require(vault_ != address(0), "vault-not-deployed");
}
// Config wBTC/GHO vault.
{
vaultConfig.vaultId = 59;
vaultConfig.supplyToken = WBTC_ADDRESS;
vaultConfig.borrowToken = GHO_ADDRESS;
vaultConfig.collateralFactor = 85 * 1e2; // 85%
vaultConfig.liquidationThreshold = 88 * 1e2; // 88%
vaultConfig.liquidationMaxLimit = 92.5 * 1e2; // 92.5%
vaultConfig.withdrawGap = 5 * 1e2; // 5%
vaultConfig.liquidationPenalty = 3 * 1e2; // 3%
vaultConfig.oracle = address(
0x687351DF42715Dd0F2ebfdeAc2C73D374E66bD90
);
address vault_ = configVault(vaultConfig);
require(vault_ != address(0), "vault-not-deployed");
}
// Config cbBTC/GHO vault.
{
vaultConfig.vaultId = 60;
vaultConfig.supplyToken = cbBTC_ADDRESS;
vaultConfig.borrowToken = GHO_ADDRESS;
vaultConfig.collateralFactor = 85 * 1e2; // 85%
vaultConfig.liquidationThreshold = 88 * 1e2; // 88%
vaultConfig.liquidationMaxLimit = 92.5 * 1e2; // 92.5%
vaultConfig.withdrawGap = 5 * 1e2; // 5%
vaultConfig.liquidationPenalty = 3 * 1e2; // 3%
vaultConfig.oracle = address(
0x8Ae43Ebc63d0C49C2478066bFf097Dc3FE05B5ac
);
address vault_ = configVault(vaultConfig);
require(vault_ != address(0), "vault-not-deployed");
}
// Set Team Multisig as auth for USDC/GHO Vault.
{
VAULT_FACTORY.setVaultAuth(getVaultAddress(61), TEAM_MULTISIG, true);
}
}
/**
* |
* | Proposal Payload Helpers |
* |__________________________________
*/
function getVaultAddress(uint256 vaultId_) public view returns (address) {
return VAULT_FACTORY.getVaultAddress(vaultId_);
}
struct VaultConfig {
uint256 vaultId;
address supplyToken;
uint8 supplyMode;
uint256 supplyExpandPercent;
uint256 supplyExpandDuration;
uint256 supplyBaseLimitInUSD;
uint256 supplyBaseLimit;
address borrowToken;
uint8 borrowMode;
uint256 borrowExpandPercent;
uint256 borrowExpandDuration;
uint256 borrowBaseLimitInUSD;
uint256 borrowBaseLimit;
uint256 borrowMaxLimitInUSD;
uint256 borrowMaxLimit;
uint256 supplyRateMagnifier;
uint256 borrowRateMagnifier;
uint256 collateralFactor;
uint256 liquidationThreshold;
uint256 liquidationMaxLimit;
uint256 withdrawGap;
uint256 liquidationPenalty;
uint256 borrowFee;
address oracle;
}
function configVault(
VaultConfig memory vaultConfig
) internal returns (address vault_) {
// Deploy vault.
vault_ = VAULT_FACTORY.getVaultAddress(vaultConfig.vaultId);
// Set user supply config for the vault on Liquidity Layer.
{
AdminModuleStructs.UserSupplyConfig[]
memory configs_ = new AdminModuleStructs.UserSupplyConfig[](1);
configs_[0] = AdminModuleStructs.UserSupplyConfig({
user: address(vault_),
token: vaultConfig.supplyToken,
mode: vaultConfig.supplyMode,
expandPercent: vaultConfig.supplyExpandPercent,
expandDuration: vaultConfig.supplyExpandDuration,
baseWithdrawalLimit: getRawAmount(
vaultConfig.supplyToken,
vaultConfig.supplyBaseLimit,
vaultConfig.supplyBaseLimitInUSD,
true
)
});
LIQUIDITY.updateUserSupplyConfigs(configs_);
}
// Set user borrow config for the vault on Liquidity Layer.
{
AdminModuleStructs.UserBorrowConfig[]
memory configs_ = new AdminModuleStructs.UserBorrowConfig[](1);
configs_[0] = AdminModuleStructs.UserBorrowConfig({
user: address(vault_),
token: vaultConfig.borrowToken,
mode: vaultConfig.borrowMode,
expandPercent: vaultConfig.borrowExpandPercent,
expandDuration: vaultConfig.borrowExpandDuration,
baseDebtCeiling: getRawAmount(
vaultConfig.borrowToken,
vaultConfig.borrowBaseLimit,
vaultConfig.borrowBaseLimitInUSD,
false
),
maxDebtCeiling: getRawAmount(
vaultConfig.borrowToken,
vaultConfig.borrowMaxLimit,
vaultConfig.borrowMaxLimitInUSD,
false
)
});
LIQUIDITY.updateUserBorrowConfigs(configs_);
}
// Update core settings on vault.
{
IFluidVaultT1(vault_).updateCoreSettings(
vaultConfig.supplyRateMagnifier,
vaultConfig.borrowRateMagnifier,
vaultConfig.collateralFactor,
vaultConfig.liquidationThreshold,
vaultConfig.liquidationMaxLimit,
vaultConfig.withdrawGap,
vaultConfig.liquidationPenalty,
vaultConfig.borrowFee
);
}
// Update oracle on vault.
{
IFluidVaultT1(vault_).updateOracle(vaultConfig.oracle);
}
// Update rebalancer on vault.
{
IFluidVaultT1(vault_).updateRebalancer(address(FLUID_RESERVE));
}
}
function getRawAmount(
address token,
uint256 amount,
uint256 amountInUSD,
bool isSupply
) public view returns (uint256) {
if (amount > 0 && amountInUSD > 0) {
revert("both usd and amount are not zero");
}
uint256 exchangePriceAndConfig_ = LIQUIDITY.readFromStorage(
LiquiditySlotsLink.calculateMappingStorageSlot(
LiquiditySlotsLink.LIQUIDITY_EXCHANGE_PRICES_MAPPING_SLOT,
token
)
);
(
uint256 supplyExchangePrice,
uint256 borrowExchangePrice
) = LiquidityCalcs.calcExchangePrices(exchangePriceAndConfig_);
uint256 usdPrice = 0;
uint256 decimals = 18;
if (token == ETH_ADDRESS) {
usdPrice = 2_500 * 1e2;
decimals = 18;
} else if (token == wstETH_ADDRESS) {
usdPrice = 2_970 * 1e2;
decimals = 18;
} else if (token == weETH_ADDRESS) {
usdPrice = 2_650 * 1e2;
decimals = 18;
} else if (token == cbBTC_ADDRESS || token == WBTC_ADDRESS) {
usdPrice = 67_750 * 1e2;
decimals = 8;
} else if (token == USDC_ADDRESS || token == USDT_ADDRESS) {
usdPrice = 1 * 1e2;
decimals = 6;
} else if (token == sUSDe_ADDRESS) {
usdPrice = 1.1 * 1e2;
decimals = 18;
} else if (token == GHO_ADDRESS || token == sUSDs_ADDRESS) {
usdPrice = 1 * 1e2;
decimals = 18;
} else {
revert("not-found");
}
uint256 exchangePrice = isSupply
? supplyExchangePrice
: borrowExchangePrice;
if (amount > 0) {
return (amount * 1e12) / exchangePrice;
} else {
return
(amountInUSD * 1e12 * (10 ** decimals)) /
((usdPrice * exchangePrice) / 1e2);
}
}
}// SPDX-License-Identifier: BUSL-1.1
pragma solidity 0.8.21;
/// @title library that represents a number in BigNumber(coefficient and exponent) format to store in smaller bits.
/// @notice the number is divided into two parts: a coefficient and an exponent. This comes at a cost of losing some precision
/// at the end of the number because the exponent simply fills it with zeroes. This precision is oftentimes negligible and can
/// result in significant gas cost reduction due to storage space reduction.
/// 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.
/// @dev roundUp is more like a increase 1, which happens everytime for the same number.
/// roundDown simply sets trailing digits after coefficientSize to zero (floor), only once for the same number.
library BigMathMinified {
/// @dev constants to use for `roundUp` input param to increase readability
bool internal constant ROUND_DOWN = false;
bool internal constant ROUND_UP = true;
/// @dev converts `normal` number to BigNumber with `exponent` and `coefficient` (or precision).
/// e.g.:
/// 5035703444687813576399599 (normal) = (coefficient[32bits], exponent[8bits])[40bits]
/// 5035703444687813576399599 (decimal) => 10000101010010110100000011111011110010100110100000000011100101001101001101011101111 (binary)
/// => 10000101010010110100000011111011000000000000000000000000000000000000000000000000000
/// ^-------------------- 51(exponent) -------------- ^
/// coefficient = 1000,0101,0100,1011,0100,0000,1111,1011 (2236301563)
/// exponent = 0011,0011 (51)
/// bigNumber = 1000,0101,0100,1011,0100,0000,1111,1011,0011,0011 (572493200179)
///
/// @param normal number which needs to be converted into Big Number
/// @param coefficientSize at max how many bits of precision there should be (64 = uint64 (64 bits precision))
/// @param exponentSize at max how many bits of exponent there should be (8 = uint8 (8 bits exponent))
/// @param roundUp signals if result should be rounded down or up
/// @return bigNumber converted bigNumber (coefficient << exponent)
function toBigNumber(
uint256 normal,
uint256 coefficientSize,
uint256 exponentSize,
bool roundUp
) internal pure returns (uint256 bigNumber) {
assembly {
let lastBit_
let number_ := normal
if gt(number_, 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF) {
number_ := shr(0x80, number_)
lastBit_ := 0x80
}
if gt(number_, 0xFFFFFFFFFFFFFFFF) {
number_ := shr(0x40, number_)
lastBit_ := add(lastBit_, 0x40)
}
if gt(number_, 0xFFFFFFFF) {
number_ := shr(0x20, number_)
lastBit_ := add(lastBit_, 0x20)
}
if gt(number_, 0xFFFF) {
number_ := shr(0x10, number_)
lastBit_ := add(lastBit_, 0x10)
}
if gt(number_, 0xFF) {
number_ := shr(0x8, number_)
lastBit_ := add(lastBit_, 0x8)
}
if gt(number_, 0xF) {
number_ := shr(0x4, number_)
lastBit_ := add(lastBit_, 0x4)
}
if gt(number_, 0x3) {
number_ := shr(0x2, number_)
lastBit_ := add(lastBit_, 0x2)
}
if gt(number_, 0x1) {
lastBit_ := add(lastBit_, 1)
}
if gt(number_, 0) {
lastBit_ := add(lastBit_, 1)
}
if lt(lastBit_, coefficientSize) {
// for throw exception
lastBit_ := coefficientSize
}
let exponent := sub(lastBit_, coefficientSize)
let coefficient := shr(exponent, normal)
if and(roundUp, gt(exponent, 0)) {
// rounding up is only needed if exponent is > 0, as otherwise the coefficient fully holds the original number
coefficient := add(coefficient, 1)
if eq(shl(coefficientSize, 1), coefficient) {
// case were coefficient was e.g. 111, with adding 1 it became 1000 (in binary) and coefficientSize 3 bits
// final coefficient would exceed it's size. -> reduce coefficent to 100 and increase exponent by 1.
coefficient := shl(sub(coefficientSize, 1), 1)
exponent := add(exponent, 1)
}
}
if iszero(lt(exponent, shl(exponentSize, 1))) {
// if exponent is >= exponentSize, the normal number is too big to fit within
// BigNumber with too small sizes for coefficient and exponent
revert(0, 0)
}
bigNumber := shl(exponentSize, coefficient)
bigNumber := add(bigNumber, exponent)
}
}
/// @dev get `normal` number from `bigNumber`, `exponentSize` and `exponentMask`
function fromBigNumber(
uint256 bigNumber,
uint256 exponentSize,
uint256 exponentMask
) internal pure returns (uint256 normal) {
assembly {
let coefficient := shr(exponentSize, bigNumber)
let exponent := and(bigNumber, exponentMask)
normal := shl(exponent, coefficient)
}
}
/// @dev gets the most significant bit `lastBit` of a `normal` number (length of given number of binary format).
/// e.g.
/// 5035703444687813576399599 = 10000101010010110100000011111011110010100110100000000011100101001101001101011101111
/// lastBit = ^--------------------------------- 83 ----------------------------------------^
function mostSignificantBit(uint256 normal) internal pure returns (uint lastBit) {
assembly {
let number_ := normal
if gt(normal, 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF) {
number_ := shr(0x80, number_)
lastBit := 0x80
}
if gt(number_, 0xFFFFFFFFFFFFFFFF) {
number_ := shr(0x40, number_)
lastBit := add(lastBit, 0x40)
}
if gt(number_, 0xFFFFFFFF) {
number_ := shr(0x20, number_)
lastBit := add(lastBit, 0x20)
}
if gt(number_, 0xFFFF) {
number_ := shr(0x10, number_)
lastBit := add(lastBit, 0x10)
}
if gt(number_, 0xFF) {
number_ := shr(0x8, number_)
lastBit := add(lastBit, 0x8)
}
if gt(number_, 0xF) {
number_ := shr(0x4, number_)
lastBit := add(lastBit, 0x4)
}
if gt(number_, 0x3) {
number_ := shr(0x2, number_)
lastBit := add(lastBit, 0x2)
}
if gt(number_, 0x1) {
lastBit := add(lastBit, 1)
}
if gt(number_, 0) {
lastBit := add(lastBit, 1)
}
}
}
}// SPDX-License-Identifier: BUSL-1.1
pragma solidity 0.8.21;
library LibsErrorTypes {
/***********************************|
| LiquidityCalcs |
|__________________________________*/
/// @notice thrown when supply or borrow exchange price is zero at calc token data (token not configured yet)
uint256 internal constant LiquidityCalcs__ExchangePriceZero = 70001;
/// @notice thrown when rate data is set to a version that is not implemented
uint256 internal constant LiquidityCalcs__UnsupportedRateVersion = 70002;
/// @notice thrown when the calculated borrow rate turns negative. This should never happen.
uint256 internal constant LiquidityCalcs__BorrowRateNegative = 70003;
/***********************************|
| SafeTransfer |
|__________________________________*/
/// @notice thrown when safe transfer from for an ERC20 fails
uint256 internal constant SafeTransfer__TransferFromFailed = 71001;
/// @notice thrown when safe transfer for an ERC20 fails
uint256 internal constant SafeTransfer__TransferFailed = 71002;
}// SPDX-License-Identifier: BUSL-1.1
pragma solidity 0.8.21;
import { LibsErrorTypes as ErrorTypes } from "./errorTypes.sol";
import { LiquiditySlotsLink } from "./liquiditySlotsLink.sol";
import { BigMathMinified } from "./bigMathMinified.sol";
/// @notice implements calculation methods used for Fluid liquidity such as updated exchange prices,
/// borrow rate, withdrawal / borrow limits, revenue amount.
library LiquidityCalcs {
error FluidLiquidityCalcsError(uint256 errorId_);
/// @notice emitted if the calculated borrow rate surpassed max borrow rate (16 bits) and was capped at maximum value 65535
event BorrowRateMaxCap();
/// @dev constants as from Liquidity variables.sol
uint256 internal constant EXCHANGE_PRICES_PRECISION = 1e12;
/// @dev Ignoring leap years
uint256 internal constant SECONDS_PER_YEAR = 365 days;
// constants used for BigMath conversion from and to storage
uint256 internal constant DEFAULT_EXPONENT_SIZE = 8;
uint256 internal constant DEFAULT_EXPONENT_MASK = 0xFF;
uint256 internal constant FOUR_DECIMALS = 1e4;
uint256 internal constant TWELVE_DECIMALS = 1e12;
uint256 internal constant X14 = 0x3fff;
uint256 internal constant X15 = 0x7fff;
uint256 internal constant X16 = 0xffff;
uint256 internal constant X18 = 0x3ffff;
uint256 internal constant X24 = 0xffffff;
uint256 internal constant X33 = 0x1ffffffff;
uint256 internal constant X64 = 0xffffffffffffffff;
///////////////////////////////////////////////////////////////////////////
////////// CALC EXCHANGE PRICES /////////
///////////////////////////////////////////////////////////////////////////
/// @dev calculates interest (exchange prices) for a token given its' exchangePricesAndConfig from storage.
/// @param exchangePricesAndConfig_ exchange prices and config packed uint256 read from storage
/// @return supplyExchangePrice_ updated supplyExchangePrice
/// @return borrowExchangePrice_ updated borrowExchangePrice
function calcExchangePrices(
uint256 exchangePricesAndConfig_
) internal view returns (uint256 supplyExchangePrice_, uint256 borrowExchangePrice_) {
// Extracting exchange prices
supplyExchangePrice_ =
(exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_SUPPLY_EXCHANGE_PRICE) &
X64;
borrowExchangePrice_ =
(exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_BORROW_EXCHANGE_PRICE) &
X64;
if (supplyExchangePrice_ == 0 || borrowExchangePrice_ == 0) {
revert FluidLiquidityCalcsError(ErrorTypes.LiquidityCalcs__ExchangePriceZero);
}
uint256 temp_ = exchangePricesAndConfig_ & X16; // temp_ = borrowRate
unchecked {
// last timestamp can not be > current timestamp
uint256 secondsSinceLastUpdate_ = block.timestamp -
((exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_LAST_TIMESTAMP) & X33);
uint256 borrowRatio_ = (exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_BORROW_RATIO) &
X15;
if (secondsSinceLastUpdate_ == 0 || temp_ == 0 || borrowRatio_ == 1) {
// if no time passed, borrow rate is 0, or no raw borrowings: no exchange price update needed
// (if borrowRatio_ == 1 means there is only borrowInterestFree, as first bit is 1 and rest is 0)
return (supplyExchangePrice_, borrowExchangePrice_);
}
// calculate new borrow exchange price.
// formula borrowExchangePriceIncrease: previous price * borrow rate * secondsSinceLastUpdate_.
// nominator is max uint112 (uint64 * uint16 * uint32). Divisor can not be 0.
borrowExchangePrice_ +=
(borrowExchangePrice_ * temp_ * secondsSinceLastUpdate_) /
(SECONDS_PER_YEAR * FOUR_DECIMALS);
// FOR SUPPLY EXCHANGE PRICE:
// all yield paid by borrowers (in mode with interest) goes to suppliers in mode with interest.
// formula: previous price * supply rate * secondsSinceLastUpdate_.
// where supply rate = (borrow rate - revenueFee%) * ratioSupplyYield. And
// ratioSupplyYield = utilization * supplyRatio * borrowRatio
//
// Example:
// supplyRawInterest is 80, supplyInterestFree is 20. totalSupply is 100. BorrowedRawInterest is 50.
// BorrowInterestFree is 10. TotalBorrow is 60. borrow rate 40%, revenueFee 10%.
// yield is 10 (so half a year must have passed).
// supplyRawInterest must become worth 89. totalSupply must become 109. BorrowedRawInterest must become 60.
// borrowInterestFree must still be 10. supplyInterestFree still 20. totalBorrow 70.
// supplyExchangePrice would have to go from 1 to 1,125 (+ 0.125). borrowExchangePrice from 1 to 1,2 (+0.2).
// utilization is 60%. supplyRatio = 20 / 80 = 25% (only 80% of lenders receiving yield).
// borrowRatio = 10 / 50 = 20% (only 83,333% of borrowers paying yield):
// x of borrowers paying yield = 100% - (20 / (100 + 20)) = 100% - 16.6666666% = 83,333%.
// ratioSupplyYield = 60% * 83,33333% * (100% + 20%) = 62,5%
// supplyRate = (40% * (100% - 10%)) * = 36% * 62,5% = 22.5%
// increase in supplyExchangePrice, assuming 100 as previous price.
// 100 * 22,5% * 1/2 (half a year) = 0,1125.
// cross-check supplyRawInterest worth = 80 * 1.1125 = 89. totalSupply worth = 89 + 20.
// -------------- 1. calculate ratioSupplyYield --------------------------------
// step1: utilization * supplyRatio (or actually part of lenders receiving yield)
// temp_ => supplyRatio (in 1e2: 100% = 10_000; 1% = 100 -> max value 16_383)
// if first bit 0 then ratio is supplyInterestFree / supplyWithInterest (supplyWithInterest is bigger)
// else ratio is supplyWithInterest / supplyInterestFree (supplyInterestFree is bigger)
temp_ = (exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_SUPPLY_RATIO) & X15;
if (temp_ == 1) {
// if no raw supply: no exchange price update needed
// (if supplyRatio_ == 1 means there is only supplyInterestFree, as first bit is 1 and rest is 0)
return (supplyExchangePrice_, borrowExchangePrice_);
}
// ratioSupplyYield precision is 1e27 as 100% for increased precision when supplyInterestFree > supplyWithInterest
if (temp_ & 1 == 1) {
// ratio is supplyWithInterest / supplyInterestFree (supplyInterestFree is bigger)
temp_ = temp_ >> 1;
// Note: case where temp_ == 0 (only supplyInterestFree, no yield) already covered by early return
// in the if statement a little above.
// based on above example but supplyRawInterest is 20, supplyInterestFree is 80. no fee.
// supplyRawInterest must become worth 30. totalSupply must become 110.
// supplyExchangePrice would have to go from 1 to 1,5. borrowExchangePrice from 1 to 1,2.
// so ratioSupplyYield must come out as 2.5 (250%).
// supplyRatio would be (20 * 10_000 / 80) = 2500. but must be inverted.
temp_ = (1e27 * FOUR_DECIMALS) / temp_; // e.g. 1e31 / 2500 = 4e27. (* 1e27 for precision)
// e.g. 5_000 * (1e27 + 4e27) / 1e27 = 25_000 (=250%).
temp_ =
// utilization * (100% + 100% / supplyRatio)
(((exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_UTILIZATION) & X14) *
(1e27 + temp_)) / // extract utilization (max 16_383 so there is no way this can overflow).
(FOUR_DECIMALS);
// max possible value of temp_ here is 16383 * (1e27 + 1e31) / 1e4 = ~1.64e31
} else {
// ratio is supplyInterestFree / supplyWithInterest (supplyWithInterest is bigger)
temp_ = temp_ >> 1;
// if temp_ == 0 then only supplyWithInterest => full yield. temp_ is already 0
// e.g. 5_000 * 10_000 + (20 * 10_000 / 80) / 10_000 = 5000 * 12500 / 10000 = 6250 (=62.5%).
temp_ =
// 1e27 * utilization * (100% + supplyRatio) / 100%
(1e27 *
((exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_UTILIZATION) & X14) * // extract utilization (max 16_383 so there is no way this can overflow).
(FOUR_DECIMALS + temp_)) /
(FOUR_DECIMALS * FOUR_DECIMALS);
// max possible temp_ value: 1e27 * 16383 * 2e4 / 1e8 = 3.2766e27
}
// from here temp_ => ratioSupplyYield (utilization * supplyRatio part) scaled by 1e27. max possible value ~1.64e31
// step2 of ratioSupplyYield: add borrowRatio (only x% of borrowers paying yield)
if (borrowRatio_ & 1 == 1) {
// ratio is borrowWithInterest / borrowInterestFree (borrowInterestFree is bigger)
borrowRatio_ = borrowRatio_ >> 1;
// borrowRatio_ => x of total bororwers paying yield. scale to 1e27.
// Note: case where borrowRatio_ == 0 (only borrowInterestFree, no yield) already covered
// at the beginning of the method by early return if `borrowRatio_ == 1`.
// based on above example but borrowRawInterest is 10, borrowInterestFree is 50. no fee. borrowRatio = 20%.
// so only 16.66% of borrowers are paying yield. so the 100% - part of the formula is not needed.
// x of borrowers paying yield = (borrowRatio / (100 + borrowRatio)) = 16.6666666%
// borrowRatio_ => x of total bororwers paying yield. scale to 1e27.
borrowRatio_ = (borrowRatio_ * 1e27) / (FOUR_DECIMALS + borrowRatio_);
// max value here for borrowRatio_ is (1e31 / (1e4 + 1e4))= 5e26 (= 50% of borrowers paying yield).
} else {
// ratio is borrowInterestFree / borrowWithInterest (borrowWithInterest is bigger)
borrowRatio_ = borrowRatio_ >> 1;
// borrowRatio_ => x of total bororwers paying yield. scale to 1e27.
// x of borrowers paying yield = 100% - (borrowRatio / (100 + borrowRatio)) = 100% - 16.6666666% = 83,333%.
borrowRatio_ = (1e27 - ((borrowRatio_ * 1e27) / (FOUR_DECIMALS + borrowRatio_)));
// borrowRatio can never be > 100%. so max subtraction can be 100% - 100% / 200%.
// or if borrowRatio_ is 0 -> 100% - 0. or if borrowRatio_ is 1 -> 100% - 1 / 101.
// max value here for borrowRatio_ is 1e27 - 0 = 1e27 (= 100% of borrowers paying yield).
}
// temp_ => ratioSupplyYield. scaled down from 1e25 = 1% each to normal percent precision 1e2 = 1%.
// max nominator value is ~1.64e31 * 1e27 = 1.64e58. max result = 1.64e8
temp_ = (FOUR_DECIMALS * temp_ * borrowRatio_) / 1e54;
// 2. calculate supply rate
// temp_ => supply rate (borrow rate - revenueFee%) * ratioSupplyYield.
// division part is done in next step to increase precision. (divided by 2x FOUR_DECIMALS, fee + borrowRate)
// Note that all calculation divisions for supplyExchangePrice are rounded down.
// Note supply rate can be bigger than the borrowRate, e.g. if there are only few lenders with interest
// but more suppliers not earning interest.
temp_ = ((exchangePricesAndConfig_ & X16) * // borrow rate
temp_ * // ratioSupplyYield
(FOUR_DECIMALS - ((exchangePricesAndConfig_ >> LiquiditySlotsLink.BITS_EXCHANGE_PRICES_FEE) & X14))); // revenueFee
// fee can not be > 100%. max possible = 65535 * ~1.64e8 * 1e4 =~1.074774e17.
// 3. calculate increase in supply exchange price
supplyExchangePrice_ += ((supplyExchangePrice_ * temp_ * secondsSinceLastUpdate_) /
(SECONDS_PER_YEAR * FOUR_DECIMALS * FOUR_DECIMALS * FOUR_DECIMALS));
// max possible nominator = max uint 64 * 1.074774e17 * max uint32 = ~8.52e45. Denominator can not be 0.
}
}
///////////////////////////////////////////////////////////////////////////
////////// CALC REVENUE /////////
///////////////////////////////////////////////////////////////////////////
/// @dev gets the `revenueAmount_` for a token given its' totalAmounts and exchangePricesAndConfig from storage
/// and the current balance of the Fluid liquidity contract for the token.
/// @param totalAmounts_ total amounts packed uint256 read from storage
/// @param exchangePricesAndConfig_ exchange prices and config packed uint256 read from storage
/// @param liquidityTokenBalance_ current balance of Liquidity contract (IERC20(token_).balanceOf(address(this)))
/// @return revenueAmount_ collectable revenue amount
function calcRevenue(
uint256 totalAmounts_,
uint256 exchangePricesAndConfig_,
uint256 liquidityTokenBalance_
) internal view returns (uint256 revenueAmount_) {
// @dev no need to super-optimize this method as it is only used by admin
// calculate the new exchange prices based on earned interest
(uint256 supplyExchangePrice_, uint256 borrowExchangePrice_) = calcExchangePrices(exchangePricesAndConfig_);
// total supply = interest free + with interest converted from raw
uint256 totalSupply_ = getTotalSupply(totalAmounts_, supplyExchangePrice_);
if (totalSupply_ > 0) {
// available revenue: balanceOf(token) + totalBorrowings - totalLendings.
revenueAmount_ = liquidityTokenBalance_ + getTotalBorrow(totalAmounts_, borrowExchangePrice_);
// ensure there is no possible case because of rounding etc. where this would revert,
// explicitly check if >
revenueAmount_ = revenueAmount_ > totalSupply_ ? revenueAmount_ - totalSupply_ : 0;
// Note: if utilization > 100% (totalSupply < totalBorrow), then all the amount above 100% utilization
// can only be revenue.
} else {
// if supply is 0, then rest of balance can be withdrawn as revenue so that no amounts get stuck
revenueAmount_ = liquidityTokenBalance_;
}
}
///////////////////////////////////////////////////////////////////////////
////////// CALC LIMITS /////////
///////////////////////////////////////////////////////////////////////////
/// @dev calculates withdrawal limit before an operate execution:
/// amount of user supply that must stay supplied (not amount that can be withdrawn).
/// i.e. if user has supplied 100m and can withdraw 5M, this method returns the 95M, not the withdrawable amount 5M
/// @param userSupplyData_ user supply data packed uint256 from storage
/// @param userSupply_ current user supply amount already extracted from `userSupplyData_` and converted from BigMath
/// @return currentWithdrawalLimit_ current withdrawal limit updated for expansion since last interaction.
/// returned value is in raw for with interest mode, normal amount for interest free mode!
function calcWithdrawalLimitBeforeOperate(
uint256 userSupplyData_,
uint256 userSupply_
) internal view returns (uint256 currentWithdrawalLimit_) {
// @dev must support handling the case where timestamp is 0 (config is set but no interactions yet).
// first tx where timestamp is 0 will enter `if (lastWithdrawalLimit_ == 0)` because lastWithdrawalLimit_ is not set yet.
// returning max withdrawal allowed, which is not exactly right but doesn't matter because the first interaction must be
// a deposit anyway. Important is that it would not revert.
// Note the first time a deposit brings the user supply amount to above the base withdrawal limit, the active limit
// is the fully expanded limit immediately.
// extract last set withdrawal limit
uint256 lastWithdrawalLimit_ = (userSupplyData_ >>
LiquiditySlotsLink.BITS_USER_SUPPLY_PREVIOUS_WITHDRAWAL_LIMIT) & X64;
lastWithdrawalLimit_ =
(lastWithdrawalLimit_ >> DEFAULT_EXPONENT_SIZE) <<
(lastWithdrawalLimit_ & DEFAULT_EXPONENT_MASK);
if (lastWithdrawalLimit_ == 0) {
// withdrawal limit is not activated. Max withdrawal allowed
return 0;
}
uint256 maxWithdrawableLimit_;
uint256 temp_;
unchecked {
// extract max withdrawable percent of user supply and
// calculate maximum withdrawable amount expandPercentage of user supply at full expansion duration elapsed
// e.g.: if 10% expandPercentage, meaning 10% is withdrawable after full expandDuration has elapsed.
// userSupply_ needs to be atleast 1e73 to overflow max limit of ~1e77 in uint256 (no token in existence where this is possible).
maxWithdrawableLimit_ =
(((userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_EXPAND_PERCENT) & X14) * userSupply_) /
FOUR_DECIMALS;
// time elapsed since last withdrawal limit was set (in seconds)
// @dev last process timestamp is guaranteed to exist for withdrawal, as a supply must have happened before.
// last timestamp can not be > current timestamp
temp_ =
block.timestamp -
((userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_LAST_UPDATE_TIMESTAMP) & X33);
}
// calculate withdrawable amount of expandPercent that is elapsed of expandDuration.
// e.g. if 60% of expandDuration has elapsed, then user should be able to withdraw 6% of user supply, down to 94%.
// Note: no explicit check for this needed, it is covered by setting minWithdrawalLimit_ if needed.
temp_ =
(maxWithdrawableLimit_ * temp_) /
// extract expand duration: After this, decrement won't happen (user can withdraw 100% of withdraw limit)
((userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_EXPAND_DURATION) & X24); // expand duration can never be 0
// calculate expanded withdrawal limit: last withdrawal limit - withdrawable amount.
// Note: withdrawable amount here can grow bigger than userSupply if timeElapsed is a lot bigger than expandDuration,
// which would cause the subtraction `lastWithdrawalLimit_ - withdrawableAmount_` to revert. In that case, set 0
// which will cause minimum (fully expanded) withdrawal limit to be set in lines below.
unchecked {
// underflow explicitly checked & handled
currentWithdrawalLimit_ = lastWithdrawalLimit_ > temp_ ? lastWithdrawalLimit_ - temp_ : 0;
// calculate minimum withdrawal limit: minimum amount of user supply that must stay supplied at full expansion.
// subtraction can not underflow as maxWithdrawableLimit_ is a percentage amount (<=100%) of userSupply_
temp_ = userSupply_ - maxWithdrawableLimit_;
}
// if withdrawal limit is decreased below minimum then set minimum
// (e.g. when more than expandDuration time has elapsed)
if (temp_ > currentWithdrawalLimit_) {
currentWithdrawalLimit_ = temp_;
}
}
/// @dev calculates withdrawal limit after an operate execution:
/// amount of user supply that must stay supplied (not amount that can be withdrawn).
/// i.e. if user has supplied 100m and can withdraw 5M, this method returns the 95M, not the withdrawable amount 5M
/// @param userSupplyData_ user supply data packed uint256 from storage
/// @param userSupply_ current user supply amount already extracted from `userSupplyData_` and added / subtracted with the executed operate amount
/// @param newWithdrawalLimit_ current withdrawal limit updated for expansion since last interaction, result from `calcWithdrawalLimitBeforeOperate`
/// @return withdrawalLimit_ updated withdrawal limit that should be written to storage. returned value is in
/// raw for with interest mode, normal amount for interest free mode!
function calcWithdrawalLimitAfterOperate(
uint256 userSupplyData_,
uint256 userSupply_,
uint256 newWithdrawalLimit_
) internal pure returns (uint256) {
// temp_ => base withdrawal limit. below this, maximum withdrawals are allowed
uint256 temp_ = (userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_BASE_WITHDRAWAL_LIMIT) & X18;
temp_ = (temp_ >> DEFAULT_EXPONENT_SIZE) << (temp_ & DEFAULT_EXPONENT_MASK);
// if user supply is below base limit then max withdrawals are allowed
if (userSupply_ < temp_) {
return 0;
}
// temp_ => withdrawal limit expandPercent (is in 1e2 decimals)
temp_ = (userSupplyData_ >> LiquiditySlotsLink.BITS_USER_SUPPLY_EXPAND_PERCENT) & X14;
unchecked {
// temp_ => minimum withdrawal limit: userSupply - max withdrawable limit (userSupply * expandPercent))
// userSupply_ needs to be atleast 1e73 to overflow max limit of ~1e77 in uint256 (no token in existence where this is possible).
// subtraction can not underflow as maxWithdrawableLimit_ is a percentage amount (<=100%) of userSupply_
temp_ = userSupply_ - ((userSupply_ * temp_) / FOUR_DECIMALS);
}
// if new (before operation) withdrawal limit is less than minimum limit then set minimum limit.
// e.g. can happen on new deposits. withdrawal limit is instantly fully expanded in a scenario where
// increased deposit amount outpaces withrawals.
if (temp_ > newWithdrawalLimit_) {
return temp_;
}
return newWithdrawalLimit_;
}
/// @dev calculates borrow limit before an operate execution:
/// total amount user borrow can reach (not borrowable amount in current operation).
/// i.e. if user has borrowed 50M and can still borrow 5M, this method returns the total 55M, not the borrowable amount 5M
/// @param userBorrowData_ user borrow data packed uint256 from storage
/// @param userBorrow_ current user borrow amount already extracted from `userBorrowData_`
/// @return currentBorrowLimit_ current borrow limit updated for expansion since last interaction. returned value is in
/// raw for with interest mode, normal amount for interest free mode!
function calcBorrowLimitBeforeOperate(
uint256 userBorrowData_,
uint256 userBorrow_
) internal view returns (uint256 currentBorrowLimit_) {
// @dev must support handling the case where timestamp is 0 (config is set but no interactions yet) -> base limit.
// first tx where timestamp is 0 will enter `if (maxExpandedBorrowLimit_ < baseBorrowLimit_)` because `userBorrow_` and thus
// `maxExpansionLimit_` and thus `maxExpandedBorrowLimit_` is 0 and `baseBorrowLimit_` can not be 0.
// temp_ = extract borrow expand percent (is in 1e2 decimals)
uint256 temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_EXPAND_PERCENT) & X14;
uint256 maxExpansionLimit_;
uint256 maxExpandedBorrowLimit_;
unchecked {
// calculate max expansion limit: Max amount limit can expand to since last interaction
// userBorrow_ needs to be atleast 1e73 to overflow max limit of ~1e77 in uint256 (no token in existence where this is possible).
maxExpansionLimit_ = ((userBorrow_ * temp_) / FOUR_DECIMALS);
// calculate max borrow limit: Max point limit can increase to since last interaction
maxExpandedBorrowLimit_ = userBorrow_ + maxExpansionLimit_;
}
// currentBorrowLimit_ = extract base borrow limit
currentBorrowLimit_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_BASE_BORROW_LIMIT) & X18;
currentBorrowLimit_ =
(currentBorrowLimit_ >> DEFAULT_EXPONENT_SIZE) <<
(currentBorrowLimit_ & DEFAULT_EXPONENT_MASK);
if (maxExpandedBorrowLimit_ < currentBorrowLimit_) {
return currentBorrowLimit_;
}
// time elapsed since last borrow limit was set (in seconds)
unchecked {
// temp_ = timeElapsed_ (last timestamp can not be > current timestamp)
temp_ =
block.timestamp -
((userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_LAST_UPDATE_TIMESTAMP) & X33); // extract last update timestamp
}
// currentBorrowLimit_ = expandedBorrowableAmount + extract last set borrow limit
currentBorrowLimit_ =
// calculate borrow limit expansion since last interaction for `expandPercent` that is elapsed of `expandDuration`.
// divisor is extract expand duration (after this, full expansion to expandPercentage happened).
((maxExpansionLimit_ * temp_) /
((userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_EXPAND_DURATION) & X24)) + // expand duration can never be 0
// extract last set borrow limit
BigMathMinified.fromBigNumber(
(userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_PREVIOUS_BORROW_LIMIT) & X64,
DEFAULT_EXPONENT_SIZE,
DEFAULT_EXPONENT_MASK
);
// if timeElapsed is bigger than expandDuration, new borrow limit would be > max expansion,
// so set to `maxExpandedBorrowLimit_` in that case.
// also covers the case where last process timestamp = 0 (timeElapsed would simply be very big)
if (currentBorrowLimit_ > maxExpandedBorrowLimit_) {
currentBorrowLimit_ = maxExpandedBorrowLimit_;
}
// temp_ = extract hard max borrow limit. Above this user can never borrow (not expandable above)
temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_MAX_BORROW_LIMIT) & X18;
temp_ = (temp_ >> DEFAULT_EXPONENT_SIZE) << (temp_ & DEFAULT_EXPONENT_MASK);
if (currentBorrowLimit_ > temp_) {
currentBorrowLimit_ = temp_;
}
}
/// @dev calculates borrow limit after an operate execution:
/// total amount user borrow can reach (not borrowable amount in current operation).
/// i.e. if user has borrowed 50M and can still borrow 5M, this method returns the total 55M, not the borrowable amount 5M
/// @param userBorrowData_ user borrow data packed uint256 from storage
/// @param userBorrow_ current user borrow amount already extracted from `userBorrowData_` and added / subtracted with the executed operate amount
/// @param newBorrowLimit_ current borrow limit updated for expansion since last interaction, result from `calcBorrowLimitBeforeOperate`
/// @return borrowLimit_ updated borrow limit that should be written to storage.
/// returned value is in raw for with interest mode, normal amount for interest free mode!
function calcBorrowLimitAfterOperate(
uint256 userBorrowData_,
uint256 userBorrow_,
uint256 newBorrowLimit_
) internal pure returns (uint256 borrowLimit_) {
// temp_ = extract borrow expand percent
uint256 temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_EXPAND_PERCENT) & X14; // (is in 1e2 decimals)
unchecked {
// borrowLimit_ = calculate maximum borrow limit at full expansion.
// userBorrow_ needs to be at least 1e73 to overflow max limit of ~1e77 in uint256 (no token in existence where this is possible).
borrowLimit_ = userBorrow_ + ((userBorrow_ * temp_) / FOUR_DECIMALS);
}
// temp_ = extract base borrow limit
temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_BASE_BORROW_LIMIT) & X18;
temp_ = (temp_ >> DEFAULT_EXPONENT_SIZE) << (temp_ & DEFAULT_EXPONENT_MASK);
if (borrowLimit_ < temp_) {
// below base limit, borrow limit is always base limit
return temp_;
}
// temp_ = extract hard max borrow limit. Above this user can never borrow (not expandable above)
temp_ = (userBorrowData_ >> LiquiditySlotsLink.BITS_USER_BORROW_MAX_BORROW_LIMIT) & X18;
temp_ = (temp_ >> DEFAULT_EXPONENT_SIZE) << (temp_ & DEFAULT_EXPONENT_MASK);
// make sure fully expanded borrow limit is not above hard max borrow limit
if (borrowLimit_ > temp_) {
borrowLimit_ = temp_;
}
// if new borrow limit (from before operate) is > max borrow limit, set max borrow limit.
// (e.g. on a repay shrinking instantly to fully expanded borrow limit from new borrow amount. shrinking is instant)
if (newBorrowLimit_ > borrowLimit_) {
return borrowLimit_;
}
return newBorrowLimit_;
}
///////////////////////////////////////////////////////////////////////////
////////// CALC RATES /////////
///////////////////////////////////////////////////////////////////////////
/// @dev Calculates new borrow rate from utilization for a token
/// @param rateData_ rate data packed uint256 from storage for the token
/// @param utilization_ totalBorrow / totalSupply. 1e4 = 100% utilization
/// @return rate_ rate for that particular token in 1e2 precision (e.g. 5% rate = 500)
function calcBorrowRateFromUtilization(uint256 rateData_, uint256 utilization_) internal returns (uint256 rate_) {
// extract rate version: 4 bits (0xF) starting from bit 0
uint256 rateVersion_ = (rateData_ & 0xF);
if (rateVersion_ == 1) {
rate_ = calcRateV1(rateData_, utilization_);
} else if (rateVersion_ == 2) {
rate_ = calcRateV2(rateData_, utilization_);
} else {
revert FluidLiquidityCalcsError(ErrorTypes.LiquidityCalcs__UnsupportedRateVersion);
}
if (rate_ > X16) {
// hard cap for borrow rate at maximum value 16 bits (65535) to make sure it does not overflow storage space.
// this is unlikely to ever happen if configs stay within expected levels.
rate_ = X16;
// emit event to more easily become aware
emit BorrowRateMaxCap();
}
}
/// @dev calculates the borrow rate based on utilization for rate data version 1 (with one kink) in 1e2 precision
/// @param rateData_ rate data packed uint256 from storage for the token
/// @param utilization_ in 1e2 (100% = 1e4)
/// @return rate_ rate in 1e2 precision
function calcRateV1(uint256 rateData_, uint256 utilization_) internal pure returns (uint256 rate_) {
/// For rate v1 (one kink) ------------------------------------------------------
/// Next 16 bits => 4 - 19 => Rate at utilization 0% (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Next 16 bits => 20- 35 => Utilization at kink1 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Next 16 bits => 36- 51 => Rate at utilization kink1 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Next 16 bits => 52- 67 => Rate at utilization 100% (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Last 188 bits => 68-255 => blank, might come in use in future
// y = mx + c.
// y is borrow rate
// x is utilization
// m = slope (m can also be negative for declining rates)
// c is constant (c can be negative)
uint256 y1_;
uint256 y2_;
uint256 x1_;
uint256 x2_;
// extract kink1: 16 bits (0xFFFF) starting from bit 20
// kink is in 1e2, same as utilization, so no conversion needed for direct comparison of the two
uint256 kink1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_UTILIZATION_AT_KINK) & X16;
if (utilization_ < kink1_) {
// if utilization is less than kink
y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_ZERO) & X16;
y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_KINK) & X16;
x1_ = 0; // 0%
x2_ = kink1_;
} else {
// else utilization is greater than kink
y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_KINK) & X16;
y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_MAX) & X16;
x1_ = kink1_;
x2_ = FOUR_DECIMALS; // 100%
}
int256 constant_;
int256 slope_;
unchecked {
// calculating slope with twelve decimal precision. m = (y2 - y1) / (x2 - x1).
// utilization of x2 can not be <= utilization of x1 (so no underflow or 0 divisor)
// y is in 1e2 so can not overflow when multiplied with TWELVE_DECIMALS
slope_ = (int256(y2_ - y1_) * int256(TWELVE_DECIMALS)) / int256((x2_ - x1_));
// calculating constant at 12 decimal precision. slope is already in 12 decimal hence only multiple with y1. c = y - mx.
// maximum y1_ value is 65535. 65535 * 1e12 can not overflow int256
// maximum slope is 65535 - 0 * TWELVE_DECIMALS / 1 = 65535 * 1e12;
// maximum x1_ is 100% (9_999 actually) => slope_ * x1_ can not overflow int256
// subtraction most extreme case would be 0 - max value slope_ * x1_ => can not underflow int256
constant_ = int256(y1_ * TWELVE_DECIMALS) - (slope_ * int256(x1_));
// calculating new borrow rate
// - slope_ max value is 65535 * 1e12,
// - utilization max value is let's say 500% (extreme case where borrow rate increases borrow amount without new supply)
// - constant max value is 65535 * 1e12
// so max values are 65535 * 1e12 * 50_000 + 65535 * 1e12 -> 3.2768*10^21, which easily fits int256
// divisor TWELVE_DECIMALS can not be 0
slope_ = (slope_ * int256(utilization_)) + constant_; // reusing `slope_` as variable for gas savings
if (slope_ < 0) {
revert FluidLiquidityCalcsError(ErrorTypes.LiquidityCalcs__BorrowRateNegative);
}
rate_ = uint256(slope_) / TWELVE_DECIMALS;
}
}
/// @dev calculates the borrow rate based on utilization for rate data version 2 (with two kinks) in 1e4 precision
/// @param rateData_ rate data packed uint256 from storage for the token
/// @param utilization_ in 1e2 (100% = 1e4)
/// @return rate_ rate in 1e4 precision
function calcRateV2(uint256 rateData_, uint256 utilization_) internal pure returns (uint256 rate_) {
/// For rate v2 (two kinks) -----------------------------------------------------
/// Next 16 bits => 4 - 19 => Rate at utilization 0% (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Next 16 bits => 20- 35 => Utilization at kink1 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Next 16 bits => 36- 51 => Rate at utilization kink1 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Next 16 bits => 52- 67 => Utilization at kink2 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Next 16 bits => 68- 83 => Rate at utilization kink2 (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Next 16 bits => 84- 99 => Rate at utilization 100% (in 1e2: 100% = 10_000; 1% = 100 -> max value 65535)
/// Last 156 bits => 100-255 => blank, might come in use in future
// y = mx + c.
// y is borrow rate
// x is utilization
// m = slope (m can also be negative for declining rates)
// c is constant (c can be negative)
uint256 y1_;
uint256 y2_;
uint256 x1_;
uint256 x2_;
// extract kink1: 16 bits (0xFFFF) starting from bit 20
// kink is in 1e2, same as utilization, so no conversion needed for direct comparison of the two
uint256 kink1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_UTILIZATION_AT_KINK1) & X16;
if (utilization_ < kink1_) {
// if utilization is less than kink1
y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_ZERO) & X16;
y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK1) & X16;
x1_ = 0; // 0%
x2_ = kink1_;
} else {
// extract kink2: 16 bits (0xFFFF) starting from bit 52
uint256 kink2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_UTILIZATION_AT_KINK2) & X16;
if (utilization_ < kink2_) {
// if utilization is less than kink2
y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK1) & X16;
y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK2) & X16;
x1_ = kink1_;
x2_ = kink2_;
} else {
// else utilization is greater than kink2
y1_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK2) & X16;
y2_ = (rateData_ >> LiquiditySlotsLink.BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_MAX) & X16;
x1_ = kink2_;
x2_ = FOUR_DECIMALS;
}
}
int256 constant_;
int256 slope_;
unchecked {
// calculating slope with twelve decimal precision. m = (y2 - y1) / (x2 - x1).
// utilization of x2 can not be <= utilization of x1 (so no underflow or 0 divisor)
// y is in 1e2 so can not overflow when multiplied with TWELVE_DECIMALS
slope_ = (int256(y2_ - y1_) * int256(TWELVE_DECIMALS)) / int256((x2_ - x1_));
// calculating constant at 12 decimal precision. slope is already in 12 decimal hence only multiple with y1. c = y - mx.
// maximum y1_ value is 65535. 65535 * 1e12 can not overflow int256
// maximum slope is 65535 - 0 * TWELVE_DECIMALS / 1 = 65535 * 1e12;
// maximum x1_ is 100% (9_999 actually) => slope_ * x1_ can not overflow int256
// subtraction most extreme case would be 0 - max value slope_ * x1_ => can not underflow int256
constant_ = int256(y1_ * TWELVE_DECIMALS) - (slope_ * int256(x1_));
// calculating new borrow rate
// - slope_ max value is 65535 * 1e12,
// - utilization max value is let's say 500% (extreme case where borrow rate increases borrow amount without new supply)
// - constant max value is 65535 * 1e12
// so max values are 65535 * 1e12 * 50_000 + 65535 * 1e12 -> 3.2768*10^21, which easily fits int256
// divisor TWELVE_DECIMALS can not be 0
slope_ = (slope_ * int256(utilization_)) + constant_; // reusing `slope_` as variable for gas savings
if (slope_ < 0) {
revert FluidLiquidityCalcsError(ErrorTypes.LiquidityCalcs__BorrowRateNegative);
}
rate_ = uint256(slope_) / TWELVE_DECIMALS;
}
}
/// @dev reads the total supply out of Liquidity packed storage `totalAmounts_` for `supplyExchangePrice_`
function getTotalSupply(
uint256 totalAmounts_,
uint256 supplyExchangePrice_
) internal pure returns (uint256 totalSupply_) {
// totalSupply_ => supplyInterestFree
totalSupply_ = (totalAmounts_ >> LiquiditySlotsLink.BITS_TOTAL_AMOUNTS_SUPPLY_INTEREST_FREE) & X64;
totalSupply_ = (totalSupply_ >> DEFAULT_EXPONENT_SIZE) << (totalSupply_ & DEFAULT_EXPONENT_MASK);
uint256 totalSupplyRaw_ = totalAmounts_ & X64; // no shifting as supplyRaw is first 64 bits
totalSupplyRaw_ = (totalSupplyRaw_ >> DEFAULT_EXPONENT_SIZE) << (totalSupplyRaw_ & DEFAULT_EXPONENT_MASK);
// totalSupply = supplyInterestFree + supplyRawInterest normalized from raw
totalSupply_ += ((totalSupplyRaw_ * supplyExchangePrice_) / EXCHANGE_PRICES_PRECISION);
}
/// @dev reads the total borrow out of Liquidity packed storage `totalAmounts_` for `borrowExchangePrice_`
function getTotalBorrow(
uint256 totalAmounts_,
uint256 borrowExchangePrice_
) internal pure returns (uint256 totalBorrow_) {
// totalBorrow_ => borrowInterestFree
// no & mask needed for borrow interest free as it occupies the last bits in the storage slot
totalBorrow_ = (totalAmounts_ >> LiquiditySlotsLink.BITS_TOTAL_AMOUNTS_BORROW_INTEREST_FREE);
totalBorrow_ = (totalBorrow_ >> DEFAULT_EXPONENT_SIZE) << (totalBorrow_ & DEFAULT_EXPONENT_MASK);
uint256 totalBorrowRaw_ = (totalAmounts_ >> LiquiditySlotsLink.BITS_TOTAL_AMOUNTS_BORROW_WITH_INTEREST) & X64;
totalBorrowRaw_ = (totalBorrowRaw_ >> DEFAULT_EXPONENT_SIZE) << (totalBorrowRaw_ & DEFAULT_EXPONENT_MASK);
// totalBorrow = borrowInterestFree + borrowRawInterest normalized from raw
totalBorrow_ += ((totalBorrowRaw_ * borrowExchangePrice_) / EXCHANGE_PRICES_PRECISION);
}
}// SPDX-License-Identifier: BUSL-1.1
pragma solidity 0.8.21;
/// @notice library that helps in reading / working with storage slot data of Fluid Liquidity.
/// @dev as all data for Fluid Liquidity is internal, any data must be fetched directly through manual
/// slot reading through this library or, if gas usage is less important, through the FluidLiquidityResolver.
library LiquiditySlotsLink {
/// @dev storage slot for status at Liquidity
uint256 internal constant LIQUIDITY_STATUS_SLOT = 1;
/// @dev storage slot for auths mapping at Liquidity
uint256 internal constant LIQUIDITY_AUTHS_MAPPING_SLOT = 2;
/// @dev storage slot for guardians mapping at Liquidity
uint256 internal constant LIQUIDITY_GUARDIANS_MAPPING_SLOT = 3;
/// @dev storage slot for user class mapping at Liquidity
uint256 internal constant LIQUIDITY_USER_CLASS_MAPPING_SLOT = 4;
/// @dev storage slot for exchangePricesAndConfig mapping at Liquidity
uint256 internal constant LIQUIDITY_EXCHANGE_PRICES_MAPPING_SLOT = 5;
/// @dev storage slot for rateData mapping at Liquidity
uint256 internal constant LIQUIDITY_RATE_DATA_MAPPING_SLOT = 6;
/// @dev storage slot for totalAmounts mapping at Liquidity
uint256 internal constant LIQUIDITY_TOTAL_AMOUNTS_MAPPING_SLOT = 7;
/// @dev storage slot for user supply double mapping at Liquidity
uint256 internal constant LIQUIDITY_USER_SUPPLY_DOUBLE_MAPPING_SLOT = 8;
/// @dev storage slot for user borrow double mapping at Liquidity
uint256 internal constant LIQUIDITY_USER_BORROW_DOUBLE_MAPPING_SLOT = 9;
/// @dev storage slot for listed tokens array at Liquidity
uint256 internal constant LIQUIDITY_LISTED_TOKENS_ARRAY_SLOT = 10;
// --------------------------------
// @dev stacked uint256 storage slots bits position data for each:
// ExchangePricesAndConfig
uint256 internal constant BITS_EXCHANGE_PRICES_BORROW_RATE = 0;
uint256 internal constant BITS_EXCHANGE_PRICES_FEE = 16;
uint256 internal constant BITS_EXCHANGE_PRICES_UTILIZATION = 30;
uint256 internal constant BITS_EXCHANGE_PRICES_UPDATE_THRESHOLD = 44;
uint256 internal constant BITS_EXCHANGE_PRICES_LAST_TIMESTAMP = 58;
uint256 internal constant BITS_EXCHANGE_PRICES_SUPPLY_EXCHANGE_PRICE = 91;
uint256 internal constant BITS_EXCHANGE_PRICES_BORROW_EXCHANGE_PRICE = 155;
uint256 internal constant BITS_EXCHANGE_PRICES_SUPPLY_RATIO = 219;
uint256 internal constant BITS_EXCHANGE_PRICES_BORROW_RATIO = 234;
// RateData:
uint256 internal constant BITS_RATE_DATA_VERSION = 0;
// RateData: V1
uint256 internal constant BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_ZERO = 4;
uint256 internal constant BITS_RATE_DATA_V1_UTILIZATION_AT_KINK = 20;
uint256 internal constant BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_KINK = 36;
uint256 internal constant BITS_RATE_DATA_V1_RATE_AT_UTILIZATION_MAX = 52;
// RateData: V2
uint256 internal constant BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_ZERO = 4;
uint256 internal constant BITS_RATE_DATA_V2_UTILIZATION_AT_KINK1 = 20;
uint256 internal constant BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK1 = 36;
uint256 internal constant BITS_RATE_DATA_V2_UTILIZATION_AT_KINK2 = 52;
uint256 internal constant BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_KINK2 = 68;
uint256 internal constant BITS_RATE_DATA_V2_RATE_AT_UTILIZATION_MAX = 84;
// TotalAmounts
uint256 internal constant BITS_TOTAL_AMOUNTS_SUPPLY_WITH_INTEREST = 0;
uint256 internal constant BITS_TOTAL_AMOUNTS_SUPPLY_INTEREST_FREE = 64;
uint256 internal constant BITS_TOTAL_AMOUNTS_BORROW_WITH_INTEREST = 128;
uint256 internal constant BITS_TOTAL_AMOUNTS_BORROW_INTEREST_FREE = 192;
// UserSupplyData
uint256 internal constant BITS_USER_SUPPLY_MODE = 0;
uint256 internal constant BITS_USER_SUPPLY_AMOUNT = 1;
uint256 internal constant BITS_USER_SUPPLY_PREVIOUS_WITHDRAWAL_LIMIT = 65;
uint256 internal constant BITS_USER_SUPPLY_LAST_UPDATE_TIMESTAMP = 129;
uint256 internal constant BITS_USER_SUPPLY_EXPAND_PERCENT = 162;
uint256 internal constant BITS_USER_SUPPLY_EXPAND_DURATION = 176;
uint256 internal constant BITS_USER_SUPPLY_BASE_WITHDRAWAL_LIMIT = 200;
uint256 internal constant BITS_USER_SUPPLY_IS_PAUSED = 255;
// UserBorrowData
uint256 internal constant BITS_USER_BORROW_MODE = 0;
uint256 internal constant BITS_USER_BORROW_AMOUNT = 1;
uint256 internal constant BITS_USER_BORROW_PREVIOUS_BORROW_LIMIT = 65;
uint256 internal constant BITS_USER_BORROW_LAST_UPDATE_TIMESTAMP = 129;
uint256 internal constant BITS_USER_BORROW_EXPAND_PERCENT = 162;
uint256 internal constant BITS_USER_BORROW_EXPAND_DURATION = 176;
uint256 internal constant BITS_USER_BORROW_BASE_BORROW_LIMIT = 200;
uint256 internal constant BITS_USER_BORROW_MAX_BORROW_LIMIT = 218;
uint256 internal constant BITS_USER_BORROW_IS_PAUSED = 255;
// --------------------------------
/// @notice Calculating the slot ID for Liquidity contract for single mapping at `slot_` for `key_`
function calculateMappingStorageSlot(uint256 slot_, address key_) internal pure returns (bytes32) {
return keccak256(abi.encode(key_, slot_));
}
/// @notice Calculating the slot ID for Liquidity contract for double mapping at `slot_` for `key1_` and `key2_`
function calculateDoubleMappingStorageSlot(
uint256 slot_,
address key1_,
address key2_
) internal pure returns (bytes32) {
bytes32 intermediateSlot_ = keccak256(abi.encode(key1_, slot_));
return keccak256(abi.encode(key2_, intermediateSlot_));
}
}{
"optimizer": {
"enabled": true,
"runs": 200
},
"evmVersion": "paris",
"outputSelection": {
"*": {
"*": [
"evm.bytecode",
"evm.deployedBytecode",
"devdoc",
"userdoc",
"metadata",
"abi"
]
}
},
"libraries": {}
}Contract Security Audit
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[{"inputs":[],"stateMutability":"nonpayable","type":"constructor"},{"inputs":[{"internalType":"uint256","name":"errorId_","type":"uint256"}],"name":"FluidLiquidityCalcsError","type":"error"},{"inputs":[],"name":"ADDRESS_THIS","outputs":[{"internalType":"address","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"FLUID_RESERVE","outputs":[{"internalType":"contract IFluidReserveContract","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"GOVERNOR","outputs":[{"internalType":"contract IGovernorBravo","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"LIQUIDITY","outputs":[{"internalType":"contract IFluidLiquidityAdmin","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"PROPOSAL_ID","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"PROPOSER","outputs":[{"internalType":"address","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"PROPOSER_AVO_MULTISIG","outputs":[{"internalType":"address","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"PROPOSER_AVO_MULTISIG_2","outputs":[{"internalType":"address","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"PROPOSER_AVO_MULTISIG_3","outputs":[{"internalType":"address","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"TEAM_MULTISIG","outputs":[{"internalType":"address","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"TIMELOCK","outputs":[{"internalType":"contract ITimelock","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"VAULT_FACTORY","outputs":[{"internalType":"contract FluidVaultFactory","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[],"name":"execute","outputs":[],"stateMutability":"nonpayable","type":"function"},{"inputs":[{"internalType":"address","name":"token","type":"address"},{"internalType":"uint256","name":"amount","type":"uint256"},{"internalType":"uint256","name":"amountInUSD","type":"uint256"},{"internalType":"bool","name":"isSupply","type":"bool"}],"name":"getRawAmount","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"stateMutability":"view","type":"function"},{"inputs":[{"internalType":"uint256","name":"vaultId_","type":"uint256"}],"name":"getVaultAddress","outputs":[{"internalType":"address","name":"","type":"address"}],"stateMutability":"view","type":"function"},{"inputs":[{"internalType":"string","name":"description","type":"string"}],"name":"propose","outputs":[],"stateMutability":"nonpayable","type":"function"},{"inputs":[],"name":"verifyProposal","outputs":[],"stateMutability":"view","type":"function"}]Contract Creation Code
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Multichain Portfolio | 31 Chains
| Chain | Token | Portfolio % | Price | Amount | Value |
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A contract address hosts a smart contract, which is a set of code stored on the blockchain that runs when predetermined conditions are met. Learn more about addresses in our Knowledge Base.