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Contract Name:
CollateralReserveInterestRateStrategy
Compiler Version
v0.5.17+commit.d19bba13
Optimization Enabled:
Yes with 200 runs
Other Settings:
istanbul EvmVersion
Contract Source Code (Solidity Standard Json-Input format)
pragma solidity ^0.5.0; /** * @dev Wrappers over Solidity's arithmetic operations with added overflow * checks. * * Arithmetic operations in Solidity wrap on overflow. This can easily result * in bugs, because programmers usually assume that an overflow raises an * error, which is the standard behavior in high level programming languages. * `SafeMath` restores this intuition by reverting the transaction when an * operation overflows. * * Using this library instead of the unchecked operations eliminates an entire * class of bugs, so it's recommended to use it always. */ library SafeMath { /** * @dev Returns the addition of two unsigned integers, reverting on * overflow. * * Counterpart to Solidity's `+` operator. * * Requirements: * - Addition cannot overflow. */ function add(uint256 a, uint256 b) internal pure returns (uint256) { uint256 c = a + b; require(c >= a, 'SafeMath: addition overflow'); return c; } /** * @dev Returns the subtraction of two unsigned integers, reverting on * overflow (when the result is negative). * * Counterpart to Solidity's `-` operator. * * Requirements: * - Subtraction cannot overflow. */ function sub(uint256 a, uint256 b) internal pure returns (uint256) { require(b <= a, 'SafeMath: subtraction overflow'); uint256 c = a - b; return c; } /** * @dev Returns the multiplication of two unsigned integers, reverting on * overflow. * * Counterpart to Solidity's `*` operator. * * Requirements: * - Multiplication cannot overflow. */ function mul(uint256 a, uint256 b) internal pure returns (uint256) { // Gas optimization: this is cheaper than requiring 'a' not being zero, but the // benefit is lost if 'b' is also tested. // See: https://github.com/OpenZeppelin/openzeppelin-solidity/pull/522 if (a == 0) { return 0; } uint256 c = a * b; require(c / a == b, 'SafeMath: multiplication overflow'); return c; } /** * @dev Returns the integer division of two unsigned integers. Reverts on * division by zero. The result is rounded towards zero. * * Counterpart to Solidity's `/` operator. Note: this function uses a * `revert` opcode (which leaves remaining gas untouched) while Solidity * uses an invalid opcode to revert (consuming all remaining gas). * * Requirements: * - The divisor cannot be zero. */ function div(uint256 a, uint256 b) internal pure returns (uint256) { // Solidity only automatically asserts when dividing by 0 require(b > 0, 'SafeMath: division by zero'); uint256 c = a / b; // assert(a == b * c + a % b); // There is no case in which this doesn't hold return c; } /** * @dev Returns the remainder of dividing two unsigned integers. (unsigned integer modulo), * Reverts when dividing by zero. * * Counterpart to Solidity's `%` operator. This function uses a `revert` * opcode (which leaves remaining gas untouched) while Solidity uses an * invalid opcode to revert (consuming all remaining gas). * * Requirements: * - The divisor cannot be zero. */ function mod(uint256 a, uint256 b) internal pure returns (uint256) { require(b != 0, 'SafeMath: modulo by zero'); return a % b; } } /** * @title WadRayMath library * @author Aave * @dev Provides mul and div function for wads (decimal numbers with 18 digits precision) and rays (decimals with 27 digits) **/ library WadRayMath { using SafeMath for uint256; uint256 internal constant WAD = 1e18; uint256 internal constant halfWAD = WAD / 2; uint256 internal constant RAY = 1e27; uint256 internal constant halfRAY = RAY / 2; uint256 internal constant WAD_RAY_RATIO = 1e9; /** * @return one ray, 1e27 **/ function ray() internal pure returns (uint256) { return RAY; } /** * @return one wad, 1e18 **/ function wad() internal pure returns (uint256) { return WAD; } /** * @return half ray, 1e27/2 **/ function halfRay() internal pure returns (uint256) { return halfRAY; } /** * @return half ray, 1e18/2 **/ function halfWad() internal pure returns (uint256) { return halfWAD; } /** * @dev multiplies two wad, rounding half up to the nearest wad * @param a wad * @param b wad * @return the result of a*b, in wad **/ function wadMul(uint256 a, uint256 b) internal pure returns (uint256) { return halfWAD.add(a.mul(b)).div(WAD); } /** * @dev divides two wad, rounding half up to the nearest wad * @param a wad * @param b wad * @return the result of a/b, in wad **/ function wadDiv(uint256 a, uint256 b) internal pure returns (uint256) { uint256 halfB = b / 2; return halfB.add(a.mul(WAD)).div(b); } /** * @dev multiplies two ray, rounding half up to the nearest ray * @param a ray * @param b ray * @return the result of a*b, in ray **/ function rayMul(uint256 a, uint256 b) internal pure returns (uint256) { return halfRAY.add(a.mul(b)).div(RAY); } /** * @dev divides two ray, rounding half up to the nearest ray * @param a ray * @param b ray * @return the result of a/b, in ray **/ function rayDiv(uint256 a, uint256 b) internal pure returns (uint256) { uint256 halfB = b / 2; return halfB.add(a.mul(RAY)).div(b); } /** * @dev casts ray down to wad * @param a ray * @return a casted to wad, rounded half up to the nearest wad **/ function rayToWad(uint256 a) internal pure returns (uint256) { uint256 halfRatio = WAD_RAY_RATIO / 2; return halfRatio.add(a).div(WAD_RAY_RATIO); } /** * @dev convert wad up to ray * @param a wad * @return a converted in ray **/ function wadToRay(uint256 a) internal pure returns (uint256) { return a.mul(WAD_RAY_RATIO); } /** * @dev calculates base^exp. The code uses the ModExp precompile * @return base^exp, in ray */ //solium-disable-next-line function rayPow(uint256 x, uint256 n) internal pure returns (uint256 z) { z = n % 2 != 0 ? x : RAY; for (n /= 2; n != 0; n /= 2) { x = rayMul(x, x); if (n % 2 != 0) { z = rayMul(z, x); } } } } /** * @dev Contract module that helps prevent reentrant calls to a function. * * Inheriting from `ReentrancyGuard` will make the `nonReentrant` modifier * available, which can be aplied to functions to make sure there are no nested * (reentrant) calls to them. * * Note that because there is a single `nonReentrant` guard, functions marked as * `nonReentrant` may not call one another. This can be worked around by making * those functions `private`, and then adding `external` `nonReentrant` entry * points to them. */ contract ReentrancyGuard { /// @dev counter to allow mutex lock with only one SSTORE operation uint256 private _guardCounter; constructor() internal { // The counter starts at one to prevent changing it from zero to a non-zero // value, which is a more expensive operation. _guardCounter = 1; } /** * @dev Prevents a contract from calling itself, directly or indirectly. * Calling a `nonReentrant` function from another `nonReentrant` * function is not supported. It is possible to prevent this from happening * by making the `nonReentrant` function external, and make it call a * `private` function that does the actual work. */ modifier nonReentrant() { _guardCounter += 1; uint256 localCounter = _guardCounter; _; require(localCounter == _guardCounter, 'ReentrancyGuard: reentrant call'); } } /** * @dev Collection of functions related to the address type, */ library Address { /** * @dev Returns true if `account` is a contract. * * This test is non-exhaustive, and there may be false-negatives: during the * execution of a contract's constructor, its address will be reported as * not containing a contract. * * > It is unsafe to assume that an address for which this function returns * false is an externally-owned account (EOA) and not a contract. */ function isContract(address account) internal view returns (bool) { // This method relies in extcodesize, which returns 0 for contracts in // construction, since the code is only stored at the end of the // constructor execution. uint256 size; // solhint-disable-next-line no-inline-assembly assembly { size := extcodesize(account) } return size > 0; } } /** * @dev Interface of the ERC20 standard as defined in the EIP. Does not include * the optional functions; to access them see `ERC20Detailed`. */ interface IERC20 { /** * @dev Returns the amount of tokens in existence. */ function totalSupply() external view returns (uint256); /** * @dev Returns the amount of tokens owned by `account`. */ function balanceOf(address account) external view returns (uint256); /** * @dev Moves `amount` tokens from the caller's account to `recipient`. * * Returns a boolean value indicating whether the operation succeeded. * * Emits a `Transfer` event. */ function transfer(address recipient, uint256 amount) external returns (bool); /** * @dev Returns the remaining number of tokens that `spender` will be * allowed to spend on behalf of `owner` through `transferFrom`. This is * zero by default. * * This value changes when `approve` or `transferFrom` are called. */ function allowance(address owner, address spender) external view returns (uint256); /** * @dev Sets `amount` as the allowance of `spender` over the caller's tokens. * * Returns a boolean value indicating whether the operation succeeded. * * > Beware that changing an allowance with this method brings the risk * that someone may use both the old and the new allowance by unfortunate * transaction ordering. One possible solution to mitigate this race * condition is to first reduce the spender's allowance to 0 and set the * desired value afterwards: * https://github.com/ethereum/EIPs/issues/20#issuecomment-263524729 * * Emits an `Approval` event. */ function approve(address spender, uint256 amount) external returns (bool); /** * @dev Moves `amount` tokens from `sender` to `recipient` using the * allowance mechanism. `amount` is then deducted from the caller's * allowance. * * Returns a boolean value indicating whether the operation succeeded. * * Emits a `Transfer` event. */ function transferFrom(address sender, address recipient, uint256 amount) external returns (bool); /** * @dev Emitted when `value` tokens are moved from one account (`from`) to * another (`to`). * * Note that `value` may be zero. */ event Transfer(address indexed from, address indexed to, uint256 value); /** * @dev Emitted when the allowance of a `spender` for an `owner` is set by * a call to `approve`. `value` is the new allowance. */ event Approval(address indexed owner, address indexed spender, uint256 value); } /** * @dev Implementation of the `IERC20` interface. * * This implementation is agnostic to the way tokens are created. This means * that a supply mechanism has to be added in a derived contract using `_mint`. * For a generic mechanism see `ERC20Mintable`. * * *For a detailed writeup see our guide [How to implement supply * mechanisms](https://forum.zeppelin.solutions/t/how-to-implement-erc20-supply-mechanisms/226).* * * We have followed general OpenZeppelin guidelines: functions revert instead * of returning `false` on failure. This behavior is nonetheless conventional * and does not conflict with the expectations of ERC20 applications. * * Additionally, an `Approval` event is emitted on calls to `transferFrom`. * This allows applications to reconstruct the allowance for all accounts just * by listening to said events. Other implementations of the EIP may not emit * these events, as it isn't required by the specification. * * Finally, the non-standard `decreaseAllowance` and `increaseAllowance` * functions have been added to mitigate the well-known issues around setting * allowances. See `IERC20.approve`. */ contract ERC20 is IERC20 { using SafeMath for uint256; mapping(address => uint256) private _balances; mapping(address => mapping(address => uint256)) private _allowances; uint256 private _totalSupply; /** * @dev See `IERC20.totalSupply`. */ function totalSupply() public view returns (uint256) { return _totalSupply; } /** * @dev See `IERC20.balanceOf`. */ function balanceOf(address account) public view returns (uint256) { return _balances[account]; } /** * @dev See `IERC20.transfer`. * * Requirements: * * - `recipient` cannot be the zero address. * - the caller must have a balance of at least `amount`. */ function transfer(address recipient, uint256 amount) public returns (bool) { _transfer(msg.sender, recipient, amount); return true; } /** * @dev See `IERC20.allowance`. */ function allowance(address owner, address spender) public view returns (uint256) { return _allowances[owner][spender]; } /** * @dev See `IERC20.approve`. * * Requirements: * * - `spender` cannot be the zero address. */ function approve(address spender, uint256 value) public returns (bool) { _approve(msg.sender, spender, value); return true; } /** * @dev See `IERC20.transferFrom`. * * Emits an `Approval` event indicating the updated allowance. This is not * required by the EIP. See the note at the beginning of `ERC20`; * * Requirements: * - `sender` and `recipient` cannot be the zero address. * - `sender` must have a balance of at least `value`. * - the caller must have allowance for `sender`'s tokens of at least * `amount`. */ function transferFrom(address sender, address recipient, uint256 amount) public returns (bool) { _transfer(sender, recipient, amount); _approve(sender, msg.sender, _allowances[sender][msg.sender].sub(amount)); return true; } /** * @dev Atomically increases the allowance granted to `spender` by the caller. * * This is an alternative to `approve` that can be used as a mitigation for * problems described in `IERC20.approve`. * * Emits an `Approval` event indicating the updated allowance. * * Requirements: * * - `spender` cannot be the zero address. */ function increaseAllowance(address spender, uint256 addedValue) public returns (bool) { _approve(msg.sender, spender, _allowances[msg.sender][spender].add(addedValue)); return true; } /** * @dev Atomically decreases the allowance granted to `spender` by the caller. * * This is an alternative to `approve` that can be used as a mitigation for * problems described in `IERC20.approve`. * * Emits an `Approval` event indicating the updated allowance. * * Requirements: * * - `spender` cannot be the zero address. * - `spender` must have allowance for the caller of at least * `subtractedValue`. */ function decreaseAllowance(address spender, uint256 subtractedValue) public returns (bool) { _approve(msg.sender, spender, _allowances[msg.sender][spender].sub(subtractedValue)); return true; } /** * @dev Moves tokens `amount` from `sender` to `recipient`. * * This is internal function is equivalent to `transfer`, and can be used to * e.g. implement automatic token fees, slashing mechanisms, etc. * * Emits a `Transfer` event. * * Requirements: * * - `sender` cannot be the zero address. * - `recipient` cannot be the zero address. * - `sender` must have a balance of at least `amount`. */ function _transfer(address sender, address recipient, uint256 amount) internal { require(sender != address(0), 'ERC20: transfer from the zero address'); require(recipient != address(0), 'ERC20: transfer to the zero address'); _balances[sender] = _balances[sender].sub(amount); _balances[recipient] = _balances[recipient].add(amount); emit Transfer(sender, recipient, amount); } /** @dev Creates `amount` tokens and assigns them to `account`, increasing * the total supply. * * Emits a `Transfer` event with `from` set to the zero address. * * Requirements * * - `to` cannot be the zero address. */ function _mint(address account, uint256 amount) internal { require(account != address(0), 'ERC20: mint to the zero address'); _totalSupply = _totalSupply.add(amount); _balances[account] = _balances[account].add(amount); emit Transfer(address(0), account, amount); } /** * @dev Destoys `amount` tokens from `account`, reducing the * total supply. * * Emits a `Transfer` event with `to` set to the zero address. * * Requirements * * - `account` cannot be the zero address. * - `account` must have at least `amount` tokens. */ function _burn(address account, uint256 value) internal { require(account != address(0), 'ERC20: burn from the zero address'); _totalSupply = _totalSupply.sub(value); _balances[account] = _balances[account].sub(value); emit Transfer(account, address(0), value); } /** * @dev Sets `amount` as the allowance of `spender` over the `owner`s tokens. * * This is internal function is equivalent to `approve`, and can be used to * e.g. set automatic allowances for certain subsystems, etc. * * Emits an `Approval` event. * * Requirements: * * - `owner` cannot be the zero address. * - `spender` cannot be the zero address. */ function _approve(address owner, address spender, uint256 value) internal { require(owner != address(0), 'ERC20: approve from the zero address'); require(spender != address(0), 'ERC20: approve to the zero address'); _allowances[owner][spender] = value; emit Approval(owner, spender, value); } /** * @dev Destoys `amount` tokens from `account`.`amount` is then deducted * from the caller's allowance. * * See `_burn` and `_approve`. */ function _burnFrom(address account, uint256 amount) internal { _burn(account, amount); _approve(account, msg.sender, _allowances[account][msg.sender].sub(amount)); } } /** * @dev Optional functions from the ERC20 standard. */ contract ERC20Detailed is IERC20 { string private _name; string private _symbol; uint8 private _decimals; /** * @dev Sets the values for `name`, `symbol`, and `decimals`. All three of * these values are immutable: they can only be set once during * construction. */ constructor(string memory name, string memory symbol, uint8 decimals) public { _name = name; _symbol = symbol; _decimals = decimals; } /** * @dev Returns the name of the token. */ function name() public view returns (string memory) { return _name; } /** * @dev Returns the symbol of the token, usually a shorter version of the * name. */ function symbol() public view returns (string memory) { return _symbol; } /** * @dev Returns the number of decimals used to get its user representation. * For example, if `decimals` equals `2`, a balance of `505` tokens should * be displayed to a user as `5,05` (`505 / 10 ** 2`). * * Tokens usually opt for a value of 18, imitating the relationship between * Ether and Wei. * * > Note that this information is only used for _display_ purposes: it in * no way affects any of the arithmetic of the contract, including * `IERC20.balanceOf` and `IERC20.transfer`. */ function decimals() public view returns (uint8) { return _decimals; } } /** * @title SafeERC20 * @dev Wrappers around ERC20 operations that throw on failure (when the token * contract returns false). Tokens that return no value (and instead revert or * throw on failure) are also supported, non-reverting calls are assumed to be * successful. * To use this library you can add a `using SafeERC20 for ERC20;` statement to your contract, * which allows you to call the safe operations as `token.safeTransfer(...)`, etc. */ library SafeERC20 { using SafeMath for uint256; using Address for address; function safeTransfer(IERC20 token, address to, uint256 value) internal { callOptionalReturn(token, abi.encodeWithSelector(token.transfer.selector, to, value)); } function safeTransferFrom(IERC20 token, address from, address to, uint256 value) internal { callOptionalReturn(token, abi.encodeWithSelector(token.transferFrom.selector, from, to, value)); } function safeApprove(IERC20 token, address spender, uint256 value) internal { // safeApprove should only be called when setting an initial allowance, // or when resetting it to zero. To increase and decrease it, use // 'safeIncreaseAllowance' and 'safeDecreaseAllowance' // solhint-disable-next-line max-line-length require( (value == 0) || (token.allowance(address(this), spender) == 0), 'SafeERC20: approve from non-zero to non-zero allowance' ); callOptionalReturn(token, abi.encodeWithSelector(token.approve.selector, spender, value)); } function safeIncreaseAllowance(IERC20 token, address spender, uint256 value) internal { uint256 newAllowance = token.allowance(address(this), spender).add(value); callOptionalReturn( token, abi.encodeWithSelector(token.approve.selector, spender, newAllowance) ); } function safeDecreaseAllowance(IERC20 token, address spender, uint256 value) internal { uint256 newAllowance = token.allowance(address(this), spender).sub(value); callOptionalReturn( token, abi.encodeWithSelector(token.approve.selector, spender, newAllowance) ); } /** * @dev Imitates a Solidity high-level call (i.e. a regular function call to a contract), relaxing the requirement * on the return value: the return value is optional (but if data is returned, it must not be false). * @param token The token targeted by the call. * @param data The call data (encoded using abi.encode or one of its variants). */ function callOptionalReturn(IERC20 token, bytes memory data) private { // We need to perform a low level call here, to bypass Solidity's return data size checking mechanism, since // we're implementing it ourselves. // A Solidity high level call has three parts: // 1. The target address is checked to verify it contains contract code // 2. The call itself is made, and success asserted // 3. The return value is decoded, which in turn checks the size of the returned data. // solhint-disable-next-line max-line-length require(address(token).isContract(), 'SafeERC20: call to non-contract'); // solhint-disable-next-line avoid-low-level-calls (bool success, bytes memory returndata) = address(token).call(data); require(success, 'SafeERC20: low-level call failed'); if (returndata.length > 0) { // Return data is optional // solhint-disable-next-line max-line-length require(abi.decode(returndata, (bool)), 'SafeERC20: ERC20 operation did not succeed'); } } } /** * @title VersionedInitializable * * @dev Helper contract to support initializer functions. To use it, replace * the constructor with a function that has the `initializer` modifier. * WARNING: Unlike constructors, initializer functions must be manually * invoked. This applies both to deploying an Initializable contract, as well * as extending an Initializable contract via inheritance. * WARNING: When used with inheritance, manual care must be taken to not invoke * a parent initializer twice, or ensure that all initializers are idempotent, * because this is not dealt with automatically as with constructors. * * @author Aave, inspired by the OpenZeppelin Initializable contract */ contract VersionedInitializable { /** * @dev Indicates that the contract has been initialized. */ uint256 private lastInitializedRevision = 0; /** * @dev Indicates that the contract is in the process of being initialized. */ bool private initializing; /** * @dev Modifier to use in the initializer function of a contract. */ modifier initializer() { uint256 revision = getRevision(); require( initializing || isConstructor() || revision > lastInitializedRevision, 'Contract instance has already been initialized' ); bool isTopLevelCall = !initializing; if (isTopLevelCall) { initializing = true; lastInitializedRevision = revision; } _; if (isTopLevelCall) { initializing = false; } } /// @dev returns the revision number of the contract. /// Needs to be defined in the inherited class as a constant. function getRevision() internal pure returns (uint256); /// @dev Returns true if and only if the function is running in the constructor function isConstructor() private view returns (bool) { // extcodesize checks the size of the code stored in an address, and // address returns the current address. Since the code is still not // deployed when running a constructor, any checks on its code size will // yield zero, making it an effective way to detect if a contract is // under construction or not. uint256 cs; //solium-disable-next-line assembly { cs := extcodesize(address) } return cs == 0; } // Reserved storage space to allow for layout changes in the future. uint256[50] private ______gap; } /** * @dev Contract module which provides a basic access control mechanism, where * there is an account (an owner) that can be granted exclusive access to * specific functions. * * This module is used through inheritance. It will make available the modifier * `onlyOwner`, which can be aplied to your functions to restrict their use to * the owner. */ contract Ownable { address private _owner; event OwnershipTransferred(address indexed previousOwner, address indexed newOwner); /** * @dev Initializes the contract setting the deployer as the initial owner. */ constructor() internal { _owner = msg.sender; emit OwnershipTransferred(address(0), _owner); } /** * @dev Returns the address of the current owner. */ function owner() public view returns (address) { return _owner; } /** * @dev Throws if called by any account other than the owner. */ modifier onlyOwner() { require(isOwner(), 'Ownable: caller is not the owner'); _; } /** * @dev Returns true if the caller is the current owner. */ function isOwner() public view returns (bool) { return msg.sender == _owner; } /** * @dev Leaves the contract without owner. It will not be possible to call * `onlyOwner` functions anymore. Can only be called by the current owner. * * > Note: Renouncing ownership will leave the contract without an owner, * thereby removing any functionality that is only available to the owner. */ function renounceOwnership() public onlyOwner { emit OwnershipTransferred(_owner, address(0)); _owner = address(0); } /** * @dev Transfers ownership of the contract to a new account (`newOwner`). * Can only be called by the current owner. */ function transferOwnership(address newOwner) public onlyOwner { _transferOwnership(newOwner); } /** * @dev Transfers ownership of the contract to a new account (`newOwner`). */ function _transferOwnership(address newOwner) internal { require(newOwner != address(0), 'Ownable: new owner is the zero address'); emit OwnershipTransferred(_owner, newOwner); _owner = newOwner; } } /** * @title Proxy * @dev Implements delegation of calls to other contracts, with proper * forwarding of return values and bubbling of failures. * It defines a fallback function that delegates all calls to the address * returned by the abstract _implementation() internal function. */ contract Proxy { /** * @dev Fallback function. * Implemented entirely in `_fallback`. */ function() external payable { _fallback(); } /** * @return The Address of the implementation. */ function _implementation() internal view returns (address); /** * @dev Delegates execution to an implementation contract. * This is a low level function that doesn't return to its internal call site. * It will return to the external caller whatever the implementation returns. * @param implementation Address to delegate. */ function _delegate(address implementation) internal { //solium-disable-next-line assembly { // Copy msg.data. We take full control of memory in this inline assembly // block because it will not return to Solidity code. We overwrite the // Solidity scratch pad at memory position 0. calldatacopy(0, 0, calldatasize) // Call the implementation. // out and outsize are 0 because we don't know the size yet. let result := delegatecall(gas, implementation, 0, calldatasize, 0, 0) // Copy the returned data. returndatacopy(0, 0, returndatasize) switch result // delegatecall returns 0 on error. case 0 { revert(0, returndatasize) } default { return(0, returndatasize) } } } /** * @dev Function that is run as the first thing in the fallback function. * Can be redefined in derived contracts to add functionality. * Redefinitions must call super._willFallback(). */ function _willFallback() internal {} /** * @dev fallback implementation. * Extracted to enable manual triggering. */ function _fallback() internal { _willFallback(); _delegate(_implementation()); } } /** * @title BaseUpgradeabilityProxy * @dev This contract implements a proxy that allows to change the * implementation address to which it will delegate. * Such a change is called an implementation upgrade. */ contract BaseUpgradeabilityProxy is Proxy { /** * @dev Emitted when the implementation is upgraded. * @param implementation Address of the new implementation. */ event Upgraded(address indexed implementation); /** * @dev Storage slot with the address of the current implementation. * This is the keccak-256 hash of "eip1967.proxy.implementation" subtracted by 1, and is * validated in the constructor. */ bytes32 internal constant IMPLEMENTATION_SLOT = 0x360894a13ba1a3210667c828492db98dca3e2076cc3735a920a3ca505d382bbc; /** * @dev Returns the current implementation. * @return Address of the current implementation */ function _implementation() internal view returns (address impl) { bytes32 slot = IMPLEMENTATION_SLOT; //solium-disable-next-line assembly { impl := sload(slot) } } /** * @dev Upgrades the proxy to a new implementation. * @param newImplementation Address of the new implementation. */ function _upgradeTo(address newImplementation) internal { _setImplementation(newImplementation); emit Upgraded(newImplementation); } /** * @dev Sets the implementation address of the proxy. * @param newImplementation Address of the new implementation. */ function _setImplementation(address newImplementation) internal { require( Address.isContract(newImplementation), 'Cannot set a proxy implementation to a non-contract address' ); bytes32 slot = IMPLEMENTATION_SLOT; //solium-disable-next-line assembly { sstore(slot, newImplementation) } } } /** * @title BaseAdminUpgradeabilityProxy * @dev This contract combines an upgradeability proxy with an authorization * mechanism for administrative tasks. * All external functions in this contract must be guarded by the * `ifAdmin` modifier. See ethereum/solidity#3864 for a Solidity * feature proposal that would enable this to be done automatically. */ contract BaseAdminUpgradeabilityProxy is BaseUpgradeabilityProxy { /** * @dev Emitted when the administration has been transferred. * @param previousAdmin Address of the previous admin. * @param newAdmin Address of the new admin. */ event AdminChanged(address previousAdmin, address newAdmin); /** * @dev Storage slot with the admin of the contract. * This is the keccak-256 hash of "eip1967.proxy.admin" subtracted by 1, and is * validated in the constructor. */ bytes32 internal constant ADMIN_SLOT = 0xb53127684a568b3173ae13b9f8a6016e243e63b6e8ee1178d6a717850b5d6103; /** * @dev Modifier to check whether the `msg.sender` is the admin. * If it is, it will run the function. Otherwise, it will delegate the call * to the implementation. */ modifier ifAdmin() { if (msg.sender == _admin()) { _; } else { _fallback(); } } /** * @return The address of the proxy admin. */ function admin() external ifAdmin returns (address) { return _admin(); } /** * @return The address of the implementation. */ function implementation() external ifAdmin returns (address) { return _implementation(); } /** * @dev Changes the admin of the proxy. * Only the current admin can call this function. * @param newAdmin Address to transfer proxy administration to. */ function changeAdmin(address newAdmin) external ifAdmin { require(newAdmin != address(0), 'Cannot change the admin of a proxy to the zero address'); emit AdminChanged(_admin(), newAdmin); _setAdmin(newAdmin); } /** * @dev Upgrade the backing implementation of the proxy. * Only the admin can call this function. * @param newImplementation Address of the new implementation. */ function upgradeTo(address newImplementation) external ifAdmin { _upgradeTo(newImplementation); } /** * @dev Upgrade the backing implementation of the proxy and call a function * on the new implementation. * This is useful to initialize the proxied contract. * @param newImplementation Address of the new implementation. * @param data Data to send as msg.data in the low level call. * It should include the signature and the parameters of the function to be called, as described in * https://solidity.readthedocs.io/en/v0.4.24/abi-spec.html#function-selector-and-argument-encoding. */ function upgradeToAndCall( address newImplementation, bytes calldata data ) external payable ifAdmin { _upgradeTo(newImplementation); (bool success, ) = newImplementation.delegatecall(data); require(success); } /** * @return The admin slot. */ function _admin() internal view returns (address adm) { bytes32 slot = ADMIN_SLOT; //solium-disable-next-line assembly { adm := sload(slot) } } /** * @dev Sets the address of the proxy admin. * @param newAdmin Address of the new proxy admin. */ function _setAdmin(address newAdmin) internal { bytes32 slot = ADMIN_SLOT; //solium-disable-next-line assembly { sstore(slot, newAdmin) } } /** * @dev Only fall back when the sender is not the admin. */ function _willFallback() internal { require(msg.sender != _admin(), 'Cannot call fallback function from the proxy admin'); super._willFallback(); } } /** * @title UpgradeabilityProxy * @dev Extends BaseUpgradeabilityProxy with a constructor for initializing * implementation and init data. */ contract UpgradeabilityProxy is BaseUpgradeabilityProxy { /** * @dev Contract constructor. * @param _logic Address of the initial implementation. * @param _data Data to send as msg.data to the implementation to initialize the proxied contract. * It should include the signature and the parameters of the function to be called, as described in * https://solidity.readthedocs.io/en/v0.4.24/abi-spec.html#function-selector-and-argument-encoding. * This parameter is optional, if no data is given the initialization call to proxied contract will be skipped. */ constructor(address _logic, bytes memory _data) public payable { assert(IMPLEMENTATION_SLOT == bytes32(uint256(keccak256('eip1967.proxy.implementation')) - 1)); _setImplementation(_logic); if (_data.length > 0) { (bool success, ) = _logic.delegatecall(_data); require(success); } } } /** * @title AdminUpgradeabilityProxy * @dev Extends from BaseAdminUpgradeabilityProxy with a constructor for * initializing the implementation, admin, and init data. */ contract AdminUpgradeabilityProxy is BaseAdminUpgradeabilityProxy, UpgradeabilityProxy { /** * Contract constructor. * @param _logic address of the initial implementation. * @param _admin Address of the proxy administrator. * @param _data Data to send as msg.data to the implementation to initialize the proxied contract. * It should include the signature and the parameters of the function to be called, as described in * https://solidity.readthedocs.io/en/v0.4.24/abi-spec.html#function-selector-and-argument-encoding. * This parameter is optional, if no data is given the initialization call to proxied contract will be skipped. */ constructor( address _logic, address _admin, bytes memory _data ) public payable UpgradeabilityProxy(_logic, _data) { assert(ADMIN_SLOT == bytes32(uint256(keccak256('eip1967.proxy.admin')) - 1)); _setAdmin(_admin); } } /** * @title InitializableUpgradeabilityProxy * @dev Extends BaseUpgradeabilityProxy with an initializer for initializing * implementation and init data. */ contract InitializableUpgradeabilityProxy is BaseUpgradeabilityProxy { /** * @dev Contract initializer. * @param _logic Address of the initial implementation. * @param _data Data to send as msg.data to the implementation to initialize the proxied contract. * It should include the signature and the parameters of the function to be called, as described in * https://solidity.readthedocs.io/en/v0.4.24/abi-spec.html#function-selector-and-argument-encoding. * This parameter is optional, if no data is given the initialization call to proxied contract will be skipped. */ function initialize(address _logic, bytes memory _data) public payable { require(_implementation() == address(0)); assert(IMPLEMENTATION_SLOT == bytes32(uint256(keccak256('eip1967.proxy.implementation')) - 1)); _setImplementation(_logic); if (_data.length > 0) { (bool success, ) = _logic.delegatecall(_data); require(success); } } } contract AddressStorage { mapping(bytes32 => address) private addresses; function getAddress(bytes32 _key) public view returns (address) { return addresses[_key]; } function _setAddress(bytes32 _key, address _value) internal { addresses[_key] = _value; } } /** * @title InitializableAdminUpgradeabilityProxy * @dev Extends from BaseAdminUpgradeabilityProxy with an initializer for * initializing the implementation, admin, and init data. */ contract InitializableAdminUpgradeabilityProxy is BaseAdminUpgradeabilityProxy, InitializableUpgradeabilityProxy { /** * Contract initializer. * @param _logic address of the initial implementation. * @param _admin Address of the proxy administrator. * @param _data Data to send as msg.data to the implementation to initialize the proxied contract. * It should include the signature and the parameters of the function to be called, as described in * https://solidity.readthedocs.io/en/v0.4.24/abi-spec.html#function-selector-and-argument-encoding. * This parameter is optional, if no data is given the initialization call to proxied contract will be skipped. */ function initialize(address _logic, address _admin, bytes memory _data) public payable { require(_implementation() == address(0)); InitializableUpgradeabilityProxy.initialize(_logic, _data); assert(ADMIN_SLOT == bytes32(uint256(keccak256('eip1967.proxy.admin')) - 1)); _setAdmin(_admin); } } /** @title ILendingPoolAddressesProvider interface @notice provides the interface to fetch the LendingPoolCore address */ contract ILendingPoolAddressesProvider { function getLendingPool() public view returns (address); function setLendingPoolImpl(address _pool) public; function getLendingPoolCore() public view returns (address payable); function setLendingPoolCoreImpl(address _lendingPoolCore) public; function getLendingPoolConfigurator() public view returns (address); function setLendingPoolConfiguratorImpl(address _configurator) public; function getLendingPoolDataProvider() public view returns (address); function setLendingPoolDataProviderImpl(address _provider) public; function getLendingPoolParametersProvider() public view returns (address); function setLendingPoolParametersProviderImpl(address _parametersProvider) public; function getTokenDistributor() public view returns (address); function setTokenDistributor(address _tokenDistributor) public; function getFeeProvider() public view returns (address); function setFeeProviderImpl(address _feeProvider) public; function getLendingPoolLiquidationManager() public view returns (address); function setLendingPoolLiquidationManager(address _manager) public; function getLendingPoolManager() public view returns (address); function setLendingPoolManager(address _lendingPoolManager) public; function getPriceOracle() public view returns (address); function setPriceOracle(address _priceOracle) public; function getLendingRateOracle() public view returns (address); function setLendingRateOracle(address _lendingRateOracle) public; } /** * @title LendingPoolAddressesProvider contract * @notice Is the main registry of the protocol. All the different components of the protocol are accessible * through the addresses provider. * @author Aave **/ contract LendingPoolAddressesProvider is Ownable, ILendingPoolAddressesProvider, AddressStorage { //events event LendingPoolUpdated(address indexed newAddress); event LendingPoolCoreUpdated(address indexed newAddress); event LendingPoolParametersProviderUpdated(address indexed newAddress); event LendingPoolManagerUpdated(address indexed newAddress); event LendingPoolConfiguratorUpdated(address indexed newAddress); event LendingPoolLiquidationManagerUpdated(address indexed newAddress); event LendingPoolDataProviderUpdated(address indexed newAddress); event EthereumAddressUpdated(address indexed newAddress); event PriceOracleUpdated(address indexed newAddress); event LendingRateOracleUpdated(address indexed newAddress); event FeeProviderUpdated(address indexed newAddress); event TokenDistributorUpdated(address indexed newAddress); event ProxyCreated(bytes32 id, address indexed newAddress); bytes32 private constant LENDING_POOL = 'LENDING_POOL'; bytes32 private constant LENDING_POOL_CORE = 'LENDING_POOL_CORE'; bytes32 private constant LENDING_POOL_CONFIGURATOR = 'LENDING_POOL_CONFIGURATOR'; bytes32 private constant LENDING_POOL_PARAMETERS_PROVIDER = 'PARAMETERS_PROVIDER'; bytes32 private constant LENDING_POOL_MANAGER = 'LENDING_POOL_MANAGER'; bytes32 private constant LENDING_POOL_LIQUIDATION_MANAGER = 'LIQUIDATION_MANAGER'; bytes32 private constant LENDING_POOL_FLASHLOAN_PROVIDER = 'FLASHLOAN_PROVIDER'; bytes32 private constant DATA_PROVIDER = 'DATA_PROVIDER'; bytes32 private constant ETHEREUM_ADDRESS = 'ETHEREUM_ADDRESS'; bytes32 private constant PRICE_ORACLE = 'PRICE_ORACLE'; bytes32 private constant LENDING_RATE_ORACLE = 'LENDING_RATE_ORACLE'; bytes32 private constant FEE_PROVIDER = 'FEE_PROVIDER'; bytes32 private constant WALLET_BALANCE_PROVIDER = 'WALLET_BALANCE_PROVIDER'; bytes32 private constant TOKEN_DISTRIBUTOR = 'TOKEN_DISTRIBUTOR'; /** * @dev returns the address of the LendingPool proxy * @return the lending pool proxy address **/ function getLendingPool() public view returns (address) { return getAddress(LENDING_POOL); } /** * @dev updates the implementation of the lending pool * @param _pool the new lending pool implementation **/ function setLendingPoolImpl(address _pool) public onlyOwner { updateImplInternal(LENDING_POOL, _pool); emit LendingPoolUpdated(_pool); } /** * @dev returns the address of the LendingPoolCore proxy * @return the lending pool core proxy address */ function getLendingPoolCore() public view returns (address payable) { address payable core = address(uint160(getAddress(LENDING_POOL_CORE))); return core; } /** * @dev updates the implementation of the lending pool core * @param _lendingPoolCore the new lending pool core implementation **/ function setLendingPoolCoreImpl(address _lendingPoolCore) public onlyOwner { updateImplInternal(LENDING_POOL_CORE, _lendingPoolCore); emit LendingPoolCoreUpdated(_lendingPoolCore); } /** * @dev returns the address of the LendingPoolConfigurator proxy * @return the lending pool configurator proxy address **/ function getLendingPoolConfigurator() public view returns (address) { return getAddress(LENDING_POOL_CONFIGURATOR); } /** * @dev updates the implementation of the lending pool configurator * @param _configurator the new lending pool configurator implementation **/ function setLendingPoolConfiguratorImpl(address _configurator) public onlyOwner { updateImplInternal(LENDING_POOL_CONFIGURATOR, _configurator); emit LendingPoolConfiguratorUpdated(_configurator); } /** * @dev returns the address of the LendingPoolDataProvider proxy * @return the lending pool data provider proxy address */ function getLendingPoolDataProvider() public view returns (address) { return getAddress(DATA_PROVIDER); } /** * @dev updates the implementation of the lending pool data provider * @param _provider the new lending pool data provider implementation **/ function setLendingPoolDataProviderImpl(address _provider) public onlyOwner { updateImplInternal(DATA_PROVIDER, _provider); emit LendingPoolDataProviderUpdated(_provider); } /** * @dev returns the address of the LendingPoolParametersProvider proxy * @return the address of the Lending pool parameters provider proxy **/ function getLendingPoolParametersProvider() public view returns (address) { return getAddress(LENDING_POOL_PARAMETERS_PROVIDER); } /** * @dev updates the implementation of the lending pool parameters provider * @param _parametersProvider the new lending pool parameters provider implementation **/ function setLendingPoolParametersProviderImpl(address _parametersProvider) public onlyOwner { updateImplInternal(LENDING_POOL_PARAMETERS_PROVIDER, _parametersProvider); emit LendingPoolParametersProviderUpdated(_parametersProvider); } /** * @dev returns the address of the FeeProvider proxy * @return the address of the Fee provider proxy **/ function getFeeProvider() public view returns (address) { return getAddress(FEE_PROVIDER); } /** * @dev updates the implementation of the FeeProvider proxy * @param _feeProvider the new lending pool fee provider implementation **/ function setFeeProviderImpl(address _feeProvider) public onlyOwner { updateImplInternal(FEE_PROVIDER, _feeProvider); emit FeeProviderUpdated(_feeProvider); } /** * @dev returns the address of the LendingPoolLiquidationManager. Since the manager is used * through delegateCall within the LendingPool contract, the proxy contract pattern does not work properly hence * the addresses are changed directly. * @return the address of the Lending pool liquidation manager **/ function getLendingPoolLiquidationManager() public view returns (address) { return getAddress(LENDING_POOL_LIQUIDATION_MANAGER); } /** * @dev updates the address of the Lending pool liquidation manager * @param _manager the new lending pool liquidation manager address **/ function setLendingPoolLiquidationManager(address _manager) public onlyOwner { _setAddress(LENDING_POOL_LIQUIDATION_MANAGER, _manager); emit LendingPoolLiquidationManagerUpdated(_manager); } /** * @dev the functions below are storing specific addresses that are outside the context of the protocol * hence the upgradable proxy pattern is not used **/ function getLendingPoolManager() public view returns (address) { return getAddress(LENDING_POOL_MANAGER); } function setLendingPoolManager(address _lendingPoolManager) public onlyOwner { _setAddress(LENDING_POOL_MANAGER, _lendingPoolManager); emit LendingPoolManagerUpdated(_lendingPoolManager); } function getPriceOracle() public view returns (address) { return getAddress(PRICE_ORACLE); } function setPriceOracle(address _priceOracle) public onlyOwner { _setAddress(PRICE_ORACLE, _priceOracle); emit PriceOracleUpdated(_priceOracle); } function getLendingRateOracle() public view returns (address) { return getAddress(LENDING_RATE_ORACLE); } function setLendingRateOracle(address _lendingRateOracle) public onlyOwner { _setAddress(LENDING_RATE_ORACLE, _lendingRateOracle); emit LendingRateOracleUpdated(_lendingRateOracle); } function getTokenDistributor() public view returns (address) { return getAddress(TOKEN_DISTRIBUTOR); } function setTokenDistributor(address _tokenDistributor) public onlyOwner { _setAddress(TOKEN_DISTRIBUTOR, _tokenDistributor); emit TokenDistributorUpdated(_tokenDistributor); } /** * @dev internal function to update the implementation of a specific component of the protocol * @param _id the id of the contract to be updated * @param _newAddress the address of the new implementation **/ function updateImplInternal(bytes32 _id, address _newAddress) internal { address payable proxyAddress = address(uint160(getAddress(_id))); InitializableAdminUpgradeabilityProxy proxy = InitializableAdminUpgradeabilityProxy( proxyAddress ); bytes memory params = abi.encodeWithSignature('initialize(address)', address(this)); if (proxyAddress == address(0)) { proxy = new InitializableAdminUpgradeabilityProxy(); proxy.initialize(_newAddress, address(this), params); _setAddress(_id, address(proxy)); emit ProxyCreated(_id, address(proxy)); } else { proxy.upgradeToAndCall(_newAddress, params); } } } contract UintStorage { mapping(bytes32 => uint256) private uints; function getUint(bytes32 _key) public view returns (uint256) { return uints[_key]; } function _setUint(bytes32 _key, uint256 _value) internal { uints[_key] = _value; } } /** * @title LendingPoolParametersProvider * @author Aave * @notice stores the configuration parameters of the Lending Pool contract **/ contract LendingPoolParametersProvider is VersionedInitializable { uint256 private constant MAX_STABLE_RATE_BORROW_SIZE_PERCENT = 25; uint256 private constant REBALANCE_DOWN_RATE_DELTA = (1e27) / 5; uint256 private constant FLASHLOAN_FEE_TOTAL = 35; uint256 private constant FLASHLOAN_FEE_PROTOCOL = 3000; uint256 private constant DATA_PROVIDER_REVISION = 0x1; function getRevision() internal pure returns (uint256) { return DATA_PROVIDER_REVISION; } /** * @dev initializes the LendingPoolParametersProvider after it's added to the proxy * @param _addressesProvider the address of the LendingPoolAddressesProvider */ function initialize(address _addressesProvider) public initializer {} /** * @dev returns the maximum stable rate borrow size, in percentage of the available liquidity. **/ function getMaxStableRateBorrowSizePercent() external pure returns (uint256) { return MAX_STABLE_RATE_BORROW_SIZE_PERCENT; } /** * @dev returns the delta between the current stable rate and the user stable rate at * which the borrow position of the user will be rebalanced (scaled down) **/ function getRebalanceDownRateDelta() external pure returns (uint256) { return REBALANCE_DOWN_RATE_DELTA; } /** * @dev returns the fee applied to a flashloan and the portion to redirect to the protocol, in basis points. **/ function getFlashLoanFeesInBips() external pure returns (uint256, uint256) { return (FLASHLOAN_FEE_TOTAL, FLASHLOAN_FEE_PROTOCOL); } } /** * @title CoreLibrary library * @author Aave * @notice Defines the data structures of the reserves and the user data **/ library CoreLibrary { using SafeMath for uint256; using WadRayMath for uint256; enum InterestRateMode { NONE, STABLE, VARIABLE } uint256 internal constant SECONDS_PER_YEAR = 365 days; struct UserReserveData { //principal amount borrowed by the user. uint256 principalBorrowBalance; //cumulated variable borrow index for the user. Expressed in ray uint256 lastVariableBorrowCumulativeIndex; //origination fee cumulated by the user uint256 originationFee; // stable borrow rate at which the user has borrowed. Expressed in ray uint256 stableBorrowRate; uint40 lastUpdateTimestamp; //defines if a specific deposit should or not be used as a collateral in borrows bool useAsCollateral; } struct ReserveData { /** * @dev refer to the whitepaper, section 1.1 basic concepts for a formal description of these properties. **/ //the liquidity index. Expressed in ray uint256 lastLiquidityCumulativeIndex; //the current supply rate. Expressed in ray uint256 currentLiquidityRate; //the total borrows of the reserve at a stable rate. Expressed in the currency decimals uint256 totalBorrowsStable; //the total borrows of the reserve at a variable rate. Expressed in the currency decimals uint256 totalBorrowsVariable; //the current variable borrow rate. Expressed in ray uint256 currentVariableBorrowRate; //the current stable borrow rate. Expressed in ray uint256 currentStableBorrowRate; //the current average stable borrow rate (weighted average of all the different stable rate loans). Expressed in ray uint256 currentAverageStableBorrowRate; //variable borrow index. Expressed in ray uint256 lastVariableBorrowCumulativeIndex; //the ltv of the reserve. Expressed in percentage (0-100) uint256 baseLTVasCollateral; //the liquidation threshold of the reserve. Expressed in percentage (0-100) uint256 liquidationThreshold; //the liquidation bonus of the reserve. Expressed in percentage uint256 liquidationBonus; //the decimals of the reserve asset uint256 decimals; /** * @dev address of the aToken representing the asset **/ address aTokenAddress; /** * @dev address of the interest rate strategy contract **/ address interestRateStrategyAddress; uint40 lastUpdateTimestamp; // borrowingEnabled = true means users can borrow from this reserve bool borrowingEnabled; // usageAsCollateralEnabled = true means users can use this reserve as collateral bool usageAsCollateralEnabled; // isStableBorrowRateEnabled = true means users can borrow at a stable rate bool isStableBorrowRateEnabled; // isActive = true means the reserve has been activated and properly configured bool isActive; // isFreezed = true means the reserve only allows repays and redeems, but not deposits, new borrowings or rate swap bool isFreezed; } /** * @dev returns the ongoing normalized income for the reserve. * a value of 1e27 means there is no income. As time passes, the income is accrued. * A value of 2*1e27 means that the income of the reserve is double the initial amount. * @param _reserve the reserve object * @return the normalized income. expressed in ray **/ function getNormalizedIncome( CoreLibrary.ReserveData storage _reserve ) internal view returns (uint256) { uint256 cumulated = calculateLinearInterest( _reserve.currentLiquidityRate, _reserve.lastUpdateTimestamp ).rayMul(_reserve.lastLiquidityCumulativeIndex); return cumulated; } /** * @dev Updates the liquidity cumulative index Ci and variable borrow cumulative index Bvc. Refer to the whitepaper for * a formal specification. * @param _self the reserve object **/ function updateCumulativeIndexes(ReserveData storage _self) internal { uint256 totalBorrows = getTotalBorrows(_self); if (totalBorrows > 0) { //only cumulating if there is any income being produced uint256 cumulatedLiquidityInterest = calculateLinearInterest( _self.currentLiquidityRate, _self.lastUpdateTimestamp ); _self.lastLiquidityCumulativeIndex = cumulatedLiquidityInterest.rayMul( _self.lastLiquidityCumulativeIndex ); uint256 cumulatedVariableBorrowInterest = calculateCompoundedInterest( _self.currentVariableBorrowRate, _self.lastUpdateTimestamp ); _self.lastVariableBorrowCumulativeIndex = cumulatedVariableBorrowInterest.rayMul( _self.lastVariableBorrowCumulativeIndex ); } } /** * @dev accumulates a predefined amount of asset to the reserve as a fixed, one time income. Used for example to accumulate * the flashloan fee to the reserve, and spread it through the depositors. * @param _self the reserve object * @param _totalLiquidity the total liquidity available in the reserve * @param _amount the amount to accomulate **/ function cumulateToLiquidityIndex( ReserveData storage _self, uint256 _totalLiquidity, uint256 _amount ) internal { uint256 amountToLiquidityRatio = _amount.wadToRay().rayDiv(_totalLiquidity.wadToRay()); uint256 cumulatedLiquidity = amountToLiquidityRatio.add(WadRayMath.ray()); _self.lastLiquidityCumulativeIndex = cumulatedLiquidity.rayMul( _self.lastLiquidityCumulativeIndex ); } /** * @dev initializes a reserve * @param _self the reserve object * @param _aTokenAddress the address of the overlying atoken contract * @param _decimals the number of decimals of the underlying asset * @param _interestRateStrategyAddress the address of the interest rate strategy contract **/ function init( ReserveData storage _self, address _aTokenAddress, uint256 _decimals, address _interestRateStrategyAddress ) external { require(_self.aTokenAddress == address(0), 'Reserve has already been initialized'); if (_self.lastLiquidityCumulativeIndex == 0) { //if the reserve has not been initialized yet _self.lastLiquidityCumulativeIndex = WadRayMath.ray(); } if (_self.lastVariableBorrowCumulativeIndex == 0) { _self.lastVariableBorrowCumulativeIndex = WadRayMath.ray(); } _self.aTokenAddress = _aTokenAddress; _self.decimals = _decimals; _self.interestRateStrategyAddress = _interestRateStrategyAddress; _self.isActive = true; _self.isFreezed = false; } /** * @dev enables borrowing on a reserve * @param _self the reserve object * @param _stableBorrowRateEnabled true if the stable borrow rate must be enabled by default, false otherwise **/ function enableBorrowing(ReserveData storage _self, bool _stableBorrowRateEnabled) external { require(_self.borrowingEnabled == false, 'Reserve is already enabled'); _self.borrowingEnabled = true; _self.isStableBorrowRateEnabled = _stableBorrowRateEnabled; } /** * @dev disables borrowing on a reserve * @param _self the reserve object **/ function disableBorrowing(ReserveData storage _self) external { _self.borrowingEnabled = false; } /** * @dev enables a reserve to be used as collateral * @param _self the reserve object * @param _baseLTVasCollateral the loan to value of the asset when used as collateral * @param _liquidationThreshold the threshold at which loans using this asset as collateral will be considered undercollateralized * @param _liquidationBonus the bonus liquidators receive to liquidate this asset **/ function enableAsCollateral( ReserveData storage _self, uint256 _baseLTVasCollateral, uint256 _liquidationThreshold, uint256 _liquidationBonus ) external { require(_self.usageAsCollateralEnabled == false, 'Reserve is already enabled as collateral'); _self.usageAsCollateralEnabled = true; _self.baseLTVasCollateral = _baseLTVasCollateral; _self.liquidationThreshold = _liquidationThreshold; _self.liquidationBonus = _liquidationBonus; if (_self.lastLiquidityCumulativeIndex == 0) _self.lastLiquidityCumulativeIndex = WadRayMath.ray(); } /** * @dev disables a reserve as collateral * @param _self the reserve object **/ function disableAsCollateral(ReserveData storage _self) external { _self.usageAsCollateralEnabled = false; } /** * @dev calculates the compounded borrow balance of a user * @param _self the userReserve object * @param _reserve the reserve object * @return the user compounded borrow balance **/ function getCompoundedBorrowBalance( CoreLibrary.UserReserveData storage _self, CoreLibrary.ReserveData storage _reserve ) internal view returns (uint256) { if (_self.principalBorrowBalance == 0) return 0; uint256 principalBorrowBalanceRay = _self.principalBorrowBalance.wadToRay(); uint256 compoundedBalance = 0; uint256 cumulatedInterest = 0; if (_self.stableBorrowRate > 0) { cumulatedInterest = calculateCompoundedInterest( _self.stableBorrowRate, _self.lastUpdateTimestamp ); } else { //variable interest cumulatedInterest = calculateCompoundedInterest( _reserve.currentVariableBorrowRate, _reserve.lastUpdateTimestamp ).rayMul(_reserve.lastVariableBorrowCumulativeIndex).rayDiv( _self.lastVariableBorrowCumulativeIndex ); } compoundedBalance = principalBorrowBalanceRay.rayMul(cumulatedInterest).rayToWad(); if (compoundedBalance == _self.principalBorrowBalance) { //solium-disable-next-line if (_self.lastUpdateTimestamp != block.timestamp) { //no interest cumulation because of the rounding - we add 1 wei //as symbolic cumulated interest to avoid interest free loans. return _self.principalBorrowBalance.add(1 wei); } } return compoundedBalance; } /** * @dev increases the total borrows at a stable rate on a specific reserve and updates the * average stable rate consequently * @param _reserve the reserve object * @param _amount the amount to add to the total borrows stable * @param _rate the rate at which the amount has been borrowed **/ function increaseTotalBorrowsStableAndUpdateAverageRate( ReserveData storage _reserve, uint256 _amount, uint256 _rate ) internal { uint256 previousTotalBorrowStable = _reserve.totalBorrowsStable; //updating reserve borrows stable _reserve.totalBorrowsStable = _reserve.totalBorrowsStable.add(_amount); //update the average stable rate //weighted average of all the borrows uint256 weightedLastBorrow = _amount.wadToRay().rayMul(_rate); uint256 weightedPreviousTotalBorrows = previousTotalBorrowStable.wadToRay().rayMul( _reserve.currentAverageStableBorrowRate ); _reserve.currentAverageStableBorrowRate = weightedLastBorrow .add(weightedPreviousTotalBorrows) .rayDiv(_reserve.totalBorrowsStable.wadToRay()); } /** * @dev decreases the total borrows at a stable rate on a specific reserve and updates the * average stable rate consequently * @param _reserve the reserve object * @param _amount the amount to substract to the total borrows stable * @param _rate the rate at which the amount has been repaid **/ function decreaseTotalBorrowsStableAndUpdateAverageRate( ReserveData storage _reserve, uint256 _amount, uint256 _rate ) internal { require(_reserve.totalBorrowsStable >= _amount, 'Invalid amount to decrease'); uint256 previousTotalBorrowStable = _reserve.totalBorrowsStable; //updating reserve borrows stable _reserve.totalBorrowsStable = _reserve.totalBorrowsStable.sub(_amount); if (_reserve.totalBorrowsStable == 0) { _reserve.currentAverageStableBorrowRate = 0; //no income if there are no stable rate borrows return; } //update the average stable rate //weighted average of all the borrows uint256 weightedLastBorrow = _amount.wadToRay().rayMul(_rate); uint256 weightedPreviousTotalBorrows = previousTotalBorrowStable.wadToRay().rayMul( _reserve.currentAverageStableBorrowRate ); require( weightedPreviousTotalBorrows >= weightedLastBorrow, "The amounts to subtract don't match" ); _reserve.currentAverageStableBorrowRate = weightedPreviousTotalBorrows .sub(weightedLastBorrow) .rayDiv(_reserve.totalBorrowsStable.wadToRay()); } /** * @dev increases the total borrows at a variable rate * @param _reserve the reserve object * @param _amount the amount to add to the total borrows variable **/ function increaseTotalBorrowsVariable(ReserveData storage _reserve, uint256 _amount) internal { _reserve.totalBorrowsVariable = _reserve.totalBorrowsVariable.add(_amount); } /** * @dev decreases the total borrows at a variable rate * @param _reserve the reserve object * @param _amount the amount to substract to the total borrows variable **/ function decreaseTotalBorrowsVariable(ReserveData storage _reserve, uint256 _amount) internal { require( _reserve.totalBorrowsVariable >= _amount, 'The amount that is being subtracted from the variable total borrows is incorrect' ); _reserve.totalBorrowsVariable = _reserve.totalBorrowsVariable.sub(_amount); } /** * @dev function to calculate the interest using a linear interest rate formula * @param _rate the interest rate, in ray * @param _lastUpdateTimestamp the timestamp of the last update of the interest * @return the interest rate linearly accumulated during the timeDelta, in ray **/ function calculateLinearInterest( uint256 _rate, uint40 _lastUpdateTimestamp ) internal view returns (uint256) { //solium-disable-next-line uint256 timeDifference = block.timestamp.sub(uint256(_lastUpdateTimestamp)); uint256 timeDelta = timeDifference.wadToRay().rayDiv(SECONDS_PER_YEAR.wadToRay()); return _rate.rayMul(timeDelta).add(WadRayMath.ray()); } /** * @dev function to calculate the interest using a compounded interest rate formula * @param _rate the interest rate, in ray * @param _lastUpdateTimestamp the timestamp of the last update of the interest * @return the interest rate compounded during the timeDelta, in ray **/ function calculateCompoundedInterest( uint256 _rate, uint40 _lastUpdateTimestamp ) internal view returns (uint256) { //solium-disable-next-line uint256 timeDifference = block.timestamp.sub(uint256(_lastUpdateTimestamp)); uint256 ratePerSecond = _rate.div(SECONDS_PER_YEAR); return ratePerSecond.add(WadRayMath.ray()).rayPow(timeDifference); } /** * @dev returns the total borrows on the reserve * @param _reserve the reserve object * @return the total borrows (stable + variable) **/ function getTotalBorrows( CoreLibrary.ReserveData storage _reserve ) internal view returns (uint256) { return _reserve.totalBorrowsStable.add(_reserve.totalBorrowsVariable); } } /** * @title IPriceOracleGetter interface * @notice Interface for the Aave price oracle. **/ interface IPriceOracleGetter { /** * @dev returns the asset price in ETH * @param _asset the address of the asset * @return the ETH price of the asset **/ function getAssetPrice(address _asset) external view returns (uint256); } /** * @title IFeeProvider interface * @notice Interface for the Aave fee provider. **/ interface IFeeProvider { function calculateLoanOriginationFee( address _user, uint256 _amount ) external view returns (uint256); function getLoanOriginationFeePercentage() external view returns (uint256); } /** * @title LendingPoolDataProvider contract * @author Aave * @notice Implements functions to fetch data from the core, and aggregate them in order to allow computation * on the compounded balances and the account balances in ETH **/ contract LendingPoolDataProvider is VersionedInitializable { using SafeMath for uint256; using WadRayMath for uint256; LendingPoolCore public core; LendingPoolAddressesProvider public addressesProvider; /** * @dev specifies the health factor threshold at which the user position is liquidated. * 1e18 by default, if the health factor drops below 1e18, the loan can be liquidated. **/ uint256 public constant HEALTH_FACTOR_LIQUIDATION_THRESHOLD = 1e18; uint256 public constant DATA_PROVIDER_REVISION = 0x1; function getRevision() internal pure returns (uint256) { return DATA_PROVIDER_REVISION; } function initialize(LendingPoolAddressesProvider _addressesProvider) public initializer { addressesProvider = _addressesProvider; core = LendingPoolCore(_addressesProvider.getLendingPoolCore()); } /** * @dev struct to hold calculateUserGlobalData() local computations **/ struct UserGlobalDataLocalVars { uint256 reserveUnitPrice; uint256 tokenUnit; uint256 compoundedLiquidityBalance; uint256 compoundedBorrowBalance; uint256 reserveDecimals; uint256 baseLtv; uint256 liquidationThreshold; uint256 originationFee; bool usageAsCollateralEnabled; bool userUsesReserveAsCollateral; address currentReserve; } /** * @dev calculates the user data across the reserves. * this includes the total liquidity/collateral/borrow balances in ETH, * the average Loan To Value, the average Liquidation Ratio, and the Health factor. * @param _user the address of the user * @return the total liquidity, total collateral, total borrow balances of the user in ETH. * also the average Ltv, liquidation threshold, and the health factor **/ function calculateUserGlobalData( address _user ) public view returns ( uint256 totalLiquidityBalanceETH, uint256 totalCollateralBalanceETH, uint256 totalBorrowBalanceETH, uint256 totalFeesETH, uint256 currentLtv, uint256 currentLiquidationThreshold, uint256 healthFactor, bool healthFactorBelowThreshold ) { IPriceOracleGetter oracle = IPriceOracleGetter(addressesProvider.getPriceOracle()); // Usage of a memory struct of vars to avoid "Stack too deep" errors due to local variables UserGlobalDataLocalVars memory vars; address[] memory reserves = core.getReserves(); for (uint256 i = 0; i < reserves.length; i++) { vars.currentReserve = reserves[i]; ( vars.compoundedLiquidityBalance, vars.compoundedBorrowBalance, vars.originationFee, vars.userUsesReserveAsCollateral ) = core.getUserBasicReserveData(vars.currentReserve, _user); if (vars.compoundedLiquidityBalance == 0 && vars.compoundedBorrowBalance == 0) { continue; } //fetch reserve data ( vars.reserveDecimals, vars.baseLtv, vars.liquidationThreshold, vars.usageAsCollateralEnabled ) = core.getReserveConfiguration(vars.currentReserve); vars.tokenUnit = 10 ** vars.reserveDecimals; vars.reserveUnitPrice = oracle.getAssetPrice(vars.currentReserve); //liquidity and collateral balance if (vars.compoundedLiquidityBalance > 0) { uint256 liquidityBalanceETH = vars .reserveUnitPrice .mul(vars.compoundedLiquidityBalance) .div(vars.tokenUnit); totalLiquidityBalanceETH = totalLiquidityBalanceETH.add(liquidityBalanceETH); if (vars.usageAsCollateralEnabled && vars.userUsesReserveAsCollateral) { totalCollateralBalanceETH = totalCollateralBalanceETH.add(liquidityBalanceETH); currentLtv = currentLtv.add(liquidityBalanceETH.mul(vars.baseLtv)); currentLiquidationThreshold = currentLiquidationThreshold.add( liquidityBalanceETH.mul(vars.liquidationThreshold) ); } } if (vars.compoundedBorrowBalance > 0) { totalBorrowBalanceETH = totalBorrowBalanceETH.add( vars.reserveUnitPrice.mul(vars.compoundedBorrowBalance).div(vars.tokenUnit) ); totalFeesETH = totalFeesETH.add( vars.originationFee.mul(vars.reserveUnitPrice).div(vars.tokenUnit) ); } } currentLtv = totalCollateralBalanceETH > 0 ? currentLtv.div(totalCollateralBalanceETH) : 0; currentLiquidationThreshold = totalCollateralBalanceETH > 0 ? currentLiquidationThreshold.div(totalCollateralBalanceETH) : 0; healthFactor = calculateHealthFactorFromBalancesInternal( totalCollateralBalanceETH, totalBorrowBalanceETH, totalFeesETH, currentLiquidationThreshold ); healthFactorBelowThreshold = healthFactor < HEALTH_FACTOR_LIQUIDATION_THRESHOLD; } struct balanceDecreaseAllowedLocalVars { uint256 decimals; uint256 collateralBalanceETH; uint256 borrowBalanceETH; uint256 totalFeesETH; uint256 currentLiquidationThreshold; uint256 reserveLiquidationThreshold; uint256 amountToDecreaseETH; uint256 collateralBalancefterDecrease; uint256 liquidationThresholdAfterDecrease; uint256 healthFactorAfterDecrease; bool reserveUsageAsCollateralEnabled; } /** * @dev check if a specific balance decrease is allowed (i.e. doesn't bring the user borrow position health factor under 1e18) * @param _reserve the address of the reserve * @param _user the address of the user * @param _amount the amount to decrease * @return true if the decrease of the balance is allowed **/ function balanceDecreaseAllowed( address _reserve, address _user, uint256 _amount ) external view returns (bool) { // Usage of a memory struct of vars to avoid "Stack too deep" errors due to local variables balanceDecreaseAllowedLocalVars memory vars; (vars.decimals, , vars.reserveLiquidationThreshold, vars.reserveUsageAsCollateralEnabled) = core .getReserveConfiguration(_reserve); if ( !vars.reserveUsageAsCollateralEnabled || !core.isUserUseReserveAsCollateralEnabled(_reserve, _user) ) { return true; //if reserve is not used as collateral, no reasons to block the transfer } ( , vars.collateralBalanceETH, vars.borrowBalanceETH, vars.totalFeesETH, , vars.currentLiquidationThreshold, , ) = calculateUserGlobalData(_user); if (vars.borrowBalanceETH == 0) { return true; //no borrows - no reasons to block the transfer } IPriceOracleGetter oracle = IPriceOracleGetter(addressesProvider.getPriceOracle()); vars.amountToDecreaseETH = oracle.getAssetPrice(_reserve).mul(_amount).div(10 ** vars.decimals); vars.collateralBalancefterDecrease = vars.collateralBalanceETH.sub(vars.amountToDecreaseETH); //if there is a borrow, there can't be 0 collateral if (vars.collateralBalancefterDecrease == 0) { return false; } vars.liquidationThresholdAfterDecrease = vars .collateralBalanceETH .mul(vars.currentLiquidationThreshold) .sub(vars.amountToDecreaseETH.mul(vars.reserveLiquidationThreshold)) .div(vars.collateralBalancefterDecrease); uint256 healthFactorAfterDecrease = calculateHealthFactorFromBalancesInternal( vars.collateralBalancefterDecrease, vars.borrowBalanceETH, vars.totalFeesETH, vars.liquidationThresholdAfterDecrease ); return healthFactorAfterDecrease > HEALTH_FACTOR_LIQUIDATION_THRESHOLD; } /** * @notice calculates the amount of collateral needed in ETH to cover a new borrow. * @param _reserve the reserve from which the user wants to borrow * @param _amount the amount the user wants to borrow * @param _fee the fee for the amount that the user needs to cover * @param _userCurrentBorrowBalanceTH the current borrow balance of the user (before the borrow) * @param _userCurrentLtv the average ltv of the user given his current collateral * @return the total amount of collateral in ETH to cover the current borrow balance + the new amount + fee **/ function calculateCollateralNeededInETH( address _reserve, uint256 _amount, uint256 _fee, uint256 _userCurrentBorrowBalanceTH, uint256 _userCurrentFeesETH, uint256 _userCurrentLtv ) external view returns (uint256) { uint256 reserveDecimals = core.getReserveDecimals(_reserve); IPriceOracleGetter oracle = IPriceOracleGetter(addressesProvider.getPriceOracle()); uint256 requestedBorrowAmountETH = oracle.getAssetPrice(_reserve).mul(_amount.add(_fee)).div( 10 ** reserveDecimals ); //price is in ether //add the current already borrowed amount to the amount requested to calculate the total collateral needed. uint256 collateralNeededInETH = _userCurrentBorrowBalanceTH .add(_userCurrentFeesETH) .add(requestedBorrowAmountETH) .mul(100) .div(_userCurrentLtv); //LTV is calculated in percentage return collateralNeededInETH; } /** * @dev calculates the equivalent amount in ETH that an user can borrow, depending on the available collateral and the * average Loan To Value. * @param collateralBalanceETH the total collateral balance * @param borrowBalanceETH the total borrow balance * @param totalFeesETH the total fees * @param ltv the average loan to value * @return the amount available to borrow in ETH for the user **/ function calculateAvailableBorrowsETHInternal( uint256 collateralBalanceETH, uint256 borrowBalanceETH, uint256 totalFeesETH, uint256 ltv ) internal view returns (uint256) { uint256 availableBorrowsETH = collateralBalanceETH.mul(ltv).div(100); //ltv is in percentage if (availableBorrowsETH < borrowBalanceETH) { return 0; } availableBorrowsETH = availableBorrowsETH.sub(borrowBalanceETH.add(totalFeesETH)); //calculate fee uint256 borrowFee = IFeeProvider(addressesProvider.getFeeProvider()) .calculateLoanOriginationFee(msg.sender, availableBorrowsETH); return availableBorrowsETH.sub(borrowFee); } /** * @dev calculates the health factor from the corresponding balances * @param collateralBalanceETH the total collateral balance in ETH * @param borrowBalanceETH the total borrow balance in ETH * @param totalFeesETH the total fees in ETH * @param liquidationThreshold the avg liquidation threshold **/ function calculateHealthFactorFromBalancesInternal( uint256 collateralBalanceETH, uint256 borrowBalanceETH, uint256 totalFeesETH, uint256 liquidationThreshold ) internal pure returns (uint256) { if (borrowBalanceETH == 0) return uint256(-1); return (collateralBalanceETH.mul(liquidationThreshold).div(100)).wadDiv( borrowBalanceETH.add(totalFeesETH) ); } /** * @dev returns the health factor liquidation threshold **/ function getHealthFactorLiquidationThreshold() public pure returns (uint256) { return HEALTH_FACTOR_LIQUIDATION_THRESHOLD; } /** * @dev accessory functions to fetch data from the lendingPoolCore **/ function getReserveConfigurationData( address _reserve ) external view returns ( uint256 ltv, uint256 liquidationThreshold, uint256 liquidationBonus, address rateStrategyAddress, bool usageAsCollateralEnabled, bool borrowingEnabled, bool stableBorrowRateEnabled, bool isActive ) { (, ltv, liquidationThreshold, usageAsCollateralEnabled) = core.getReserveConfiguration( _reserve ); stableBorrowRateEnabled = core.getReserveIsStableBorrowRateEnabled(_reserve); borrowingEnabled = core.isReserveBorrowingEnabled(_reserve); isActive = core.getReserveIsActive(_reserve); liquidationBonus = core.getReserveLiquidationBonus(_reserve); rateStrategyAddress = core.getReserveInterestRateStrategyAddress(_reserve); } function getReserveData( address _reserve ) external view returns ( uint256 totalLiquidity, uint256 availableLiquidity, uint256 totalBorrowsStable, uint256 totalBorrowsVariable, uint256 liquidityRate, uint256 variableBorrowRate, uint256 stableBorrowRate, uint256 averageStableBorrowRate, uint256 utilizationRate, uint256 liquidityIndex, uint256 variableBorrowIndex, address aTokenAddress, uint40 lastUpdateTimestamp ) { totalLiquidity = core.getReserveTotalLiquidity(_reserve); availableLiquidity = core.getReserveAvailableLiquidity(_reserve); totalBorrowsStable = core.getReserveTotalBorrowsStable(_reserve); totalBorrowsVariable = core.getReserveTotalBorrowsVariable(_reserve); liquidityRate = core.getReserveCurrentLiquidityRate(_reserve); variableBorrowRate = core.getReserveCurrentVariableBorrowRate(_reserve); stableBorrowRate = core.getReserveCurrentStableBorrowRate(_reserve); averageStableBorrowRate = core.getReserveCurrentAverageStableBorrowRate(_reserve); utilizationRate = core.getReserveUtilizationRate(_reserve); liquidityIndex = core.getReserveLiquidityCumulativeIndex(_reserve); variableBorrowIndex = core.getReserveVariableBorrowsCumulativeIndex(_reserve); aTokenAddress = core.getReserveATokenAddress(_reserve); lastUpdateTimestamp = core.getReserveLastUpdate(_reserve); } function getUserAccountData( address _user ) external view returns ( uint256 totalLiquidityETH, uint256 totalCollateralETH, uint256 totalBorrowsETH, uint256 totalFeesETH, uint256 availableBorrowsETH, uint256 currentLiquidationThreshold, uint256 ltv, uint256 healthFactor ) { ( totalLiquidityETH, totalCollateralETH, totalBorrowsETH, totalFeesETH, ltv, currentLiquidationThreshold, healthFactor, ) = calculateUserGlobalData(_user); availableBorrowsETH = calculateAvailableBorrowsETHInternal( totalCollateralETH, totalBorrowsETH, totalFeesETH, ltv ); } function getUserReserveData( address _reserve, address _user ) external view returns ( uint256 currentATokenBalance, uint256 currentBorrowBalance, uint256 principalBorrowBalance, uint256 borrowRateMode, uint256 borrowRate, uint256 liquidityRate, uint256 originationFee, uint256 variableBorrowIndex, uint256 lastUpdateTimestamp, bool usageAsCollateralEnabled ) { currentATokenBalance = AToken(core.getReserveATokenAddress(_reserve)).balanceOf(_user); CoreLibrary.InterestRateMode mode = core.getUserCurrentBorrowRateMode(_reserve, _user); (principalBorrowBalance, currentBorrowBalance, ) = core.getUserBorrowBalances(_reserve, _user); //default is 0, if mode == CoreLibrary.InterestRateMode.NONE if (mode == CoreLibrary.InterestRateMode.STABLE) { borrowRate = core.getUserCurrentStableBorrowRate(_reserve, _user); } else if (mode == CoreLibrary.InterestRateMode.VARIABLE) { borrowRate = core.getReserveCurrentVariableBorrowRate(_reserve); } borrowRateMode = uint256(mode); liquidityRate = core.getReserveCurrentLiquidityRate(_reserve); originationFee = core.getUserOriginationFee(_reserve, _user); variableBorrowIndex = core.getUserVariableBorrowCumulativeIndex(_reserve, _user); lastUpdateTimestamp = core.getUserLastUpdate(_reserve, _user); usageAsCollateralEnabled = core.isUserUseReserveAsCollateralEnabled(_reserve, _user); } } /** * @title Aave ERC20 AToken * * @dev Implementation of the interest bearing token for the DLP protocol. * @author Aave */ contract AToken is ERC20, ERC20Detailed { using WadRayMath for uint256; uint256 public constant UINT_MAX_VALUE = uint256(-1); /** * @dev emitted after the redeem action * @param _from the address performing the redeem * @param _value the amount to be redeemed * @param _fromBalanceIncrease the cumulated balance since the last update of the user * @param _fromIndex the last index of the user **/ event Redeem( address indexed _from, uint256 _value, uint256 _fromBalanceIncrease, uint256 _fromIndex ); /** * @dev emitted after the mint action * @param _from the address performing the mint * @param _value the amount to be minted * @param _fromBalanceIncrease the cumulated balance since the last update of the user * @param _fromIndex the last index of the user **/ event MintOnDeposit( address indexed _from, uint256 _value, uint256 _fromBalanceIncrease, uint256 _fromIndex ); /** * @dev emitted during the liquidation action, when the liquidator reclaims the underlying * asset * @param _from the address from which the tokens are being burned * @param _value the amount to be burned * @param _fromBalanceIncrease the cumulated balance since the last update of the user * @param _fromIndex the last index of the user **/ event BurnOnLiquidation( address indexed _from, uint256 _value, uint256 _fromBalanceIncrease, uint256 _fromIndex ); /** * @dev emitted during the transfer action * @param _from the address from which the tokens are being transferred * @param _to the adress of the destination * @param _value the amount to be minted * @param _fromBalanceIncrease the cumulated balance since the last update of the user * @param _toBalanceIncrease the cumulated balance since the last update of the destination * @param _fromIndex the last index of the user * @param _toIndex the last index of the liquidator **/ event BalanceTransfer( address indexed _from, address indexed _to, uint256 _value, uint256 _fromBalanceIncrease, uint256 _toBalanceIncrease, uint256 _fromIndex, uint256 _toIndex ); /** * @dev emitted when the accumulation of the interest * by an user is redirected to another user * @param _from the address from which the interest is being redirected * @param _to the adress of the destination * @param _fromBalanceIncrease the cumulated balance since the last update of the user * @param _fromIndex the last index of the user **/ event InterestStreamRedirected( address indexed _from, address indexed _to, uint256 _redirectedBalance, uint256 _fromBalanceIncrease, uint256 _fromIndex ); /** * @dev emitted when the redirected balance of an user is being updated * @param _targetAddress the address of which the balance is being updated * @param _targetBalanceIncrease the cumulated balance since the last update of the target * @param _targetIndex the last index of the user * @param _redirectedBalanceAdded the redirected balance being added * @param _redirectedBalanceRemoved the redirected balance being removed **/ event RedirectedBalanceUpdated( address indexed _targetAddress, uint256 _targetBalanceIncrease, uint256 _targetIndex, uint256 _redirectedBalanceAdded, uint256 _redirectedBalanceRemoved ); event InterestRedirectionAllowanceChanged(address indexed _from, address indexed _to); address public underlyingAssetAddress; mapping(address => uint256) private userIndexes; mapping(address => address) private interestRedirectionAddresses; mapping(address => uint256) private redirectedBalances; mapping(address => address) private interestRedirectionAllowances; LendingPoolAddressesProvider private addressesProvider; LendingPoolCore private core; LendingPool private pool; LendingPoolDataProvider private dataProvider; modifier onlyLendingPool() { require(msg.sender == address(pool), 'The caller of this function must be a lending pool'); _; } modifier whenTransferAllowed(address _from, uint256 _amount) { require(isTransferAllowed(_from, _amount), 'Transfer cannot be allowed.'); _; } constructor( LendingPoolAddressesProvider _addressesProvider, address _underlyingAsset, uint8 _underlyingAssetDecimals, string memory _name, string memory _symbol ) public ERC20Detailed(_name, _symbol, _underlyingAssetDecimals) { addressesProvider = _addressesProvider; core = LendingPoolCore(addressesProvider.getLendingPoolCore()); pool = LendingPool(addressesProvider.getLendingPool()); dataProvider = LendingPoolDataProvider(addressesProvider.getLendingPoolDataProvider()); underlyingAssetAddress = _underlyingAsset; } /** * @notice ERC20 implementation internal function backing transfer() and transferFrom() * @dev validates the transfer before allowing it. NOTE: This is not standard ERC20 behavior **/ function _transfer( address _from, address _to, uint256 _amount ) internal whenTransferAllowed(_from, _amount) { executeTransferInternal(_from, _to, _amount); } /** * @dev redirects the interest generated to a target address. * when the interest is redirected, the user balance is added to * the recepient redirected balance. * @param _to the address to which the interest will be redirected **/ function redirectInterestStream(address _to) external { redirectInterestStreamInternal(msg.sender, _to); } /** * @dev redirects the interest generated by _from to a target address. * when the interest is redirected, the user balance is added to * the recepient redirected balance. The caller needs to have allowance on * the interest redirection to be able to execute the function. * @param _from the address of the user whom interest is being redirected * @param _to the address to which the interest will be redirected **/ function redirectInterestStreamOf(address _from, address _to) external { require( msg.sender == interestRedirectionAllowances[_from], 'Caller is not allowed to redirect the interest of the user' ); redirectInterestStreamInternal(_from, _to); } /** * @dev gives allowance to an address to execute the interest redirection * on behalf of the caller. * @param _to the address to which the interest will be redirected. Pass address(0) to reset * the allowance. **/ function allowInterestRedirectionTo(address _to) external { require(_to != msg.sender, 'User cannot give allowance to himself'); interestRedirectionAllowances[msg.sender] = _to; emit InterestRedirectionAllowanceChanged(msg.sender, _to); } /** * @dev redeems aToken for the underlying asset * @param _amount the amount being redeemed **/ function redeem(uint256 _amount) external { require(_amount > 0, 'Amount to redeem needs to be > 0'); //cumulates the balance of the user (, uint256 currentBalance, uint256 balanceIncrease, uint256 index) = cumulateBalanceInternal( msg.sender ); uint256 amountToRedeem = _amount; //if amount is equal to uint(-1), the user wants to redeem everything if (_amount == UINT_MAX_VALUE) { amountToRedeem = currentBalance; } require(amountToRedeem <= currentBalance, 'User cannot redeem more than the available balance'); //check that the user is allowed to redeem the amount require(isTransferAllowed(msg.sender, amountToRedeem), 'Transfer cannot be allowed.'); //if the user is redirecting his interest towards someone else, //we update the redirected balance of the redirection address by adding the accrued interest, //and removing the amount to redeem updateRedirectedBalanceOfRedirectionAddressInternal( msg.sender, balanceIncrease, amountToRedeem ); // burns tokens equivalent to the amount requested _burn(msg.sender, amountToRedeem); bool userIndexReset = false; //reset the user data if the remaining balance is 0 if (currentBalance.sub(amountToRedeem) == 0) { userIndexReset = resetDataOnZeroBalanceInternal(msg.sender); } // executes redeem of the underlying asset pool.redeemUnderlying( underlyingAssetAddress, msg.sender, amountToRedeem, currentBalance.sub(amountToRedeem) ); emit Redeem(msg.sender, amountToRedeem, balanceIncrease, userIndexReset ? 0 : index); } /** * @dev mints token in the event of users depositing the underlying asset into the lending pool * only lending pools can call this function * @param _account the address receiving the minted tokens * @param _amount the amount of tokens to mint */ function mintOnDeposit(address _account, uint256 _amount) external onlyLendingPool { //cumulates the balance of the user (, , uint256 balanceIncrease, uint256 index) = cumulateBalanceInternal(_account); //if the user is redirecting his interest towards someone else, //we update the redirected balance of the redirection address by adding the accrued interest //and the amount deposited updateRedirectedBalanceOfRedirectionAddressInternal(_account, balanceIncrease.add(_amount), 0); //mint an equivalent amount of tokens to cover the new deposit _mint(_account, _amount); emit MintOnDeposit(_account, _amount, balanceIncrease, index); } /** * @dev burns token in the event of a borrow being liquidated, in case the liquidators reclaims the underlying asset * Transfer of the liquidated asset is executed by the lending pool contract. * only lending pools can call this function * @param _account the address from which burn the aTokens * @param _value the amount to burn **/ function burnOnLiquidation(address _account, uint256 _value) external onlyLendingPool { //cumulates the balance of the user being liquidated (, uint256 accountBalance, uint256 balanceIncrease, uint256 index) = cumulateBalanceInternal( _account ); //adds the accrued interest and substracts the burned amount to //the redirected balance updateRedirectedBalanceOfRedirectionAddressInternal(_account, balanceIncrease, _value); //burns the requested amount of tokens _burn(_account, _value); bool userIndexReset = false; //reset the user data if the remaining balance is 0 if (accountBalance.sub(_value) == 0) { userIndexReset = resetDataOnZeroBalanceInternal(_account); } emit BurnOnLiquidation(_account, _value, balanceIncrease, userIndexReset ? 0 : index); } /** * @dev transfers tokens in the event of a borrow being liquidated, in case the liquidators reclaims the aToken * only lending pools can call this function * @param _from the address from which transfer the aTokens * @param _to the destination address * @param _value the amount to transfer **/ function transferOnLiquidation( address _from, address _to, uint256 _value ) external onlyLendingPool { //being a normal transfer, the Transfer() and BalanceTransfer() are emitted //so no need to emit a specific event here executeTransferInternal(_from, _to, _value); } /** * @dev calculates the balance of the user, which is the * principal balance + interest generated by the principal balance + interest generated by the redirected balance * @param _user the user for which the balance is being calculated * @return the total balance of the user **/ function balanceOf(address _user) public view returns (uint256) { //current principal balance of the user uint256 currentPrincipalBalance = super.balanceOf(_user); //balance redirected by other users to _user for interest rate accrual uint256 redirectedBalance = redirectedBalances[_user]; if (currentPrincipalBalance == 0 && redirectedBalance == 0) { return 0; } //if the _user is not redirecting the interest to anybody, accrues //the interest for himself if (interestRedirectionAddresses[_user] == address(0)) { //accruing for himself means that both the principal balance and //the redirected balance partecipate in the interest return calculateCumulatedBalanceInternal(_user, currentPrincipalBalance.add(redirectedBalance)) .sub(redirectedBalance); } else { //if the user redirected the interest, then only the redirected //balance generates interest. In that case, the interest generated //by the redirected balance is added to the current principal balance. return currentPrincipalBalance.add( calculateCumulatedBalanceInternal(_user, redirectedBalance).sub(redirectedBalance) ); } } /** * @dev returns the principal balance of the user. The principal balance is the last * updated stored balance, which does not consider the perpetually accruing interest. * @param _user the address of the user * @return the principal balance of the user **/ function principalBalanceOf(address _user) external view returns (uint256) { return super.balanceOf(_user); } /** * @dev calculates the total supply of the specific aToken * since the balance of every single user increases over time, the total supply * does that too. * @return the current total supply **/ function totalSupply() public view returns (uint256) { uint256 currentSupplyPrincipal = super.totalSupply(); if (currentSupplyPrincipal == 0) { return 0; } return currentSupplyPrincipal .wadToRay() .rayMul(core.getReserveNormalizedIncome(underlyingAssetAddress)) .rayToWad(); } /** * @dev Used to validate transfers before actually executing them. * @param _user address of the user to check * @param _amount the amount to check * @return true if the _user can transfer _amount, false otherwise **/ function isTransferAllowed(address _user, uint256 _amount) public view returns (bool) { return dataProvider.balanceDecreaseAllowed(underlyingAssetAddress, _user, _amount); } /** * @dev returns the last index of the user, used to calculate the balance of the user * @param _user address of the user * @return the last user index **/ function getUserIndex(address _user) external view returns (uint256) { return userIndexes[_user]; } /** * @dev returns the address to which the interest is redirected * @param _user address of the user * @return 0 if there is no redirection, an address otherwise **/ function getInterestRedirectionAddress(address _user) external view returns (address) { return interestRedirectionAddresses[_user]; } /** * @dev returns the redirected balance of the user. The redirected balance is the balance * redirected by other accounts to the user, that is accrueing interest for him. * @param _user address of the user * @return the total redirected balance **/ function getRedirectedBalance(address _user) external view returns (uint256) { return redirectedBalances[_user]; } /** * @dev accumulates the accrued interest of the user to the principal balance * @param _user the address of the user for which the interest is being accumulated * @return the previous principal balance, the new principal balance, the balance increase * and the new user index **/ function cumulateBalanceInternal( address _user ) internal returns (uint256, uint256, uint256, uint256) { uint256 previousPrincipalBalance = super.balanceOf(_user); //calculate the accrued interest since the last accumulation uint256 balanceIncrease = balanceOf(_user).sub(previousPrincipalBalance); //mints an amount of tokens equivalent to the amount accumulated _mint(_user, balanceIncrease); //updates the user index uint256 index = userIndexes[_user] = core.getReserveNormalizedIncome(underlyingAssetAddress); return ( previousPrincipalBalance, previousPrincipalBalance.add(balanceIncrease), balanceIncrease, index ); } /** * @dev updates the redirected balance of the user. If the user is not redirecting his * interest, nothing is executed. * @param _user the address of the user for which the interest is being accumulated * @param _balanceToAdd the amount to add to the redirected balance * @param _balanceToRemove the amount to remove from the redirected balance **/ function updateRedirectedBalanceOfRedirectionAddressInternal( address _user, uint256 _balanceToAdd, uint256 _balanceToRemove ) internal { address redirectionAddress = interestRedirectionAddresses[_user]; //if there isn't any redirection, nothing to be done if (redirectionAddress == address(0)) { return; } //compound balances of the redirected address (, , uint256 balanceIncrease, uint256 index) = cumulateBalanceInternal(redirectionAddress); //updating the redirected balance redirectedBalances[redirectionAddress] = redirectedBalances[redirectionAddress] .add(_balanceToAdd) .sub(_balanceToRemove); //if the interest of redirectionAddress is also being redirected, we need to update //the redirected balance of the redirection target by adding the balance increase address targetOfRedirectionAddress = interestRedirectionAddresses[redirectionAddress]; if (targetOfRedirectionAddress != address(0)) { redirectedBalances[targetOfRedirectionAddress] = redirectedBalances[ targetOfRedirectionAddress ].add(balanceIncrease); } emit RedirectedBalanceUpdated( redirectionAddress, balanceIncrease, index, _balanceToAdd, _balanceToRemove ); } /** * @dev calculate the interest accrued by _user on a specific balance * @param _user the address of the user for which the interest is being accumulated * @param _balance the balance on which the interest is calculated * @return the interest rate accrued **/ function calculateCumulatedBalanceInternal( address _user, uint256 _balance ) internal view returns (uint256) { return _balance .wadToRay() .rayMul(core.getReserveNormalizedIncome(underlyingAssetAddress)) .rayDiv(userIndexes[_user]) .rayToWad(); } /** * @dev executes the transfer of aTokens, invoked by both _transfer() and * transferOnLiquidation() * @param _from the address from which transfer the aTokens * @param _to the destination address * @param _value the amount to transfer **/ function executeTransferInternal(address _from, address _to, uint256 _value) internal { require(_value > 0, 'Transferred amount needs to be greater than zero'); //cumulate the balance of the sender ( , uint256 fromBalance, uint256 fromBalanceIncrease, uint256 fromIndex ) = cumulateBalanceInternal(_from); //cumulate the balance of the receiver (, , uint256 toBalanceIncrease, uint256 toIndex) = cumulateBalanceInternal(_to); //if the sender is redirecting his interest towards someone else, //adds to the redirected balance the accrued interest and removes the amount //being transferred updateRedirectedBalanceOfRedirectionAddressInternal(_from, fromBalanceIncrease, _value); //if the receiver is redirecting his interest towards someone else, //adds to the redirected balance the accrued interest and the amount //being transferred updateRedirectedBalanceOfRedirectionAddressInternal(_to, toBalanceIncrease.add(_value), 0); //performs the transfer super._transfer(_from, _to, _value); bool fromIndexReset = false; //reset the user data if the remaining balance is 0 if (fromBalance.sub(_value) == 0) { fromIndexReset = resetDataOnZeroBalanceInternal(_from); } emit BalanceTransfer( _from, _to, _value, fromBalanceIncrease, toBalanceIncrease, fromIndexReset ? 0 : fromIndex, toIndex ); } /** * @dev executes the redirection of the interest from one address to another. * immediately after redirection, the destination address will start to accrue interest. * @param _from the address from which transfer the aTokens * @param _to the destination address **/ function redirectInterestStreamInternal(address _from, address _to) internal { address currentRedirectionAddress = interestRedirectionAddresses[_from]; require(_to != currentRedirectionAddress, 'Interest is already redirected to the user'); //accumulates the accrued interest to the principal ( uint256 previousPrincipalBalance, uint256 fromBalance, uint256 balanceIncrease, uint256 fromIndex ) = cumulateBalanceInternal(_from); require(fromBalance > 0, 'Interest stream can only be redirected if there is a valid balance'); //if the user is already redirecting the interest to someone, before changing //the redirection address we substract the redirected balance of the previous //recipient if (currentRedirectionAddress != address(0)) { updateRedirectedBalanceOfRedirectionAddressInternal(_from, 0, previousPrincipalBalance); } //if the user is redirecting the interest back to himself, //we simply set to 0 the interest redirection address if (_to == _from) { interestRedirectionAddresses[_from] = address(0); emit InterestStreamRedirected(_from, address(0), fromBalance, balanceIncrease, fromIndex); return; } //first set the redirection address to the new recipient interestRedirectionAddresses[_from] = _to; //adds the user balance to the redirected balance of the destination updateRedirectedBalanceOfRedirectionAddressInternal(_from, fromBalance, 0); emit InterestStreamRedirected(_from, _to, fromBalance, balanceIncrease, fromIndex); } /** * @dev function to reset the interest stream redirection and the user index, if the * user has no balance left. * @param _user the address of the user * @return true if the user index has also been reset, false otherwise. useful to emit the proper user index value **/ function resetDataOnZeroBalanceInternal(address _user) internal returns (bool) { //if the user has 0 principal balance, the interest stream redirection gets reset interestRedirectionAddresses[_user] = address(0); //emits a InterestStreamRedirected event to notify that the redirection has been reset emit InterestStreamRedirected(_user, address(0), 0, 0, 0); //if the redirected balance is also 0, we clear up the user index if (redirectedBalances[_user] == 0) { userIndexes[_user] = 0; return true; } else { return false; } } } /** * @title IFlashLoanReceiver interface * @notice Interface for the Aave fee IFlashLoanReceiver. * @author Aave * @dev implement this interface to develop a flashloan-compatible flashLoanReceiver contract **/ interface IFlashLoanReceiver { function executeOperation( address _reserve, uint256 _amount, uint256 _fee, bytes calldata _params ) external; } /** * @title ILendingRateOracle interface * @notice Interface for the Aave borrow rate oracle. Provides the average market borrow rate to be used as a base for the stable borrow rate calculations **/ interface ILendingRateOracle { /** @dev returns the market borrow rate in ray **/ function getMarketBorrowRate(address _asset) external view returns (uint256); /** @dev sets the market borrow rate. Rate value must be in ray **/ function setMarketBorrowRate(address _asset, uint256 _rate) external; } /** @title IReserveInterestRateStrategyInterface interface @notice Interface for the calculation of the interest rates. */ interface IReserveInterestRateStrategy { /** * @dev returns the base variable borrow rate, in rays */ function getBaseVariableBorrowRate() external view returns (uint256); /** * @dev calculates the liquidity, stable, and variable rates depending on the current utilization rate * and the base parameters * */ function calculateInterestRates( address _reserve, uint256 _utilizationRate, uint256 _totalBorrowsStable, uint256 _totalBorrowsVariable, uint256 _averageStableBorrowRate ) external view returns (uint256 liquidityRate, uint256 stableBorrowRate, uint256 variableBorrowRate); } library EthAddressLib { /** * @dev returns the address used within the protocol to identify ETH * @return the address assigned to ETH */ function ethAddress() internal pure returns (address) { return 0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE; } } /** * @title LendingPoolCore contract * @author Aave * @notice Holds the state of the lending pool and all the funds deposited * @dev NOTE: The core does not enforce security checks on the update of the state * (eg, updateStateOnBorrow() does not enforce that borrowed is enabled on the reserve). * The check that an action can be performed is a duty of the overlying LendingPool contract. **/ contract LendingPoolCore is VersionedInitializable { using SafeMath for uint256; using WadRayMath for uint256; using CoreLibrary for CoreLibrary.ReserveData; using CoreLibrary for CoreLibrary.UserReserveData; using SafeERC20 for ERC20; using Address for address payable; /** * @dev Emitted when the state of a reserve is updated * @param reserve the address of the reserve * @param liquidityRate the new liquidity rate * @param stableBorrowRate the new stable borrow rate * @param variableBorrowRate the new variable borrow rate * @param liquidityIndex the new liquidity index * @param variableBorrowIndex the new variable borrow index **/ event ReserveUpdated( address indexed reserve, uint256 liquidityRate, uint256 stableBorrowRate, uint256 variableBorrowRate, uint256 liquidityIndex, uint256 variableBorrowIndex ); address public lendingPoolAddress; LendingPoolAddressesProvider public addressesProvider; /** * @dev only lending pools can use functions affected by this modifier **/ modifier onlyLendingPool() { require(lendingPoolAddress == msg.sender, 'The caller must be a lending pool contract'); _; } /** * @dev only lending pools configurator can use functions affected by this modifier **/ modifier onlyLendingPoolConfigurator() { require( addressesProvider.getLendingPoolConfigurator() == msg.sender, 'The caller must be a lending pool configurator contract' ); _; } mapping(address => CoreLibrary.ReserveData) internal reserves; mapping(address => mapping(address => CoreLibrary.UserReserveData)) internal usersReserveData; address[] public reservesList; uint256 public constant CORE_REVISION = 0x4; /** * @dev returns the revision number of the contract **/ function getRevision() internal pure returns (uint256) { return CORE_REVISION; } /** * @dev initializes the Core contract, invoked upon registration on the AddressesProvider * @param _addressesProvider the addressesProvider contract **/ function initialize(LendingPoolAddressesProvider _addressesProvider) public initializer { addressesProvider = _addressesProvider; refreshConfigInternal(); } /** * @dev updates the state of the core as a result of a deposit action * @param _reserve the address of the reserve in which the deposit is happening * @param _user the address of the the user depositing * @param _amount the amount being deposited * @param _isFirstDeposit true if the user is depositing for the first time **/ function updateStateOnDeposit( address _reserve, address _user, uint256 _amount, bool _isFirstDeposit ) external onlyLendingPool { reserves[_reserve].updateCumulativeIndexes(); updateReserveInterestRatesAndTimestampInternal(_reserve, _amount, 0); if (_isFirstDeposit) { //if this is the first deposit of the user, we configure the deposit as enabled to be used as collateral setUserUseReserveAsCollateral(_reserve, _user, true); } } /** * @dev updates the state of the core as a result of a redeem action * @param _reserve the address of the reserve in which the redeem is happening * @param _user the address of the the user redeeming * @param _amountRedeemed the amount being redeemed * @param _userRedeemedEverything true if the user is redeeming everything **/ function updateStateOnRedeem( address _reserve, address _user, uint256 _amountRedeemed, bool _userRedeemedEverything ) external onlyLendingPool { //compound liquidity and variable borrow interests reserves[_reserve].updateCumulativeIndexes(); updateReserveInterestRatesAndTimestampInternal(_reserve, 0, _amountRedeemed); //if user redeemed everything the useReserveAsCollateral flag is reset if (_userRedeemedEverything) { setUserUseReserveAsCollateral(_reserve, _user, false); } } /** * @dev updates the state of the core as a result of a flashloan action * @param _reserve the address of the reserve in which the flashloan is happening * @param _income the income of the protocol as a result of the action **/ function updateStateOnFlashLoan( address _reserve, uint256 _availableLiquidityBefore, uint256 _income, uint256 _protocolFee ) external onlyLendingPool { transferFlashLoanProtocolFeeInternal(_reserve, _protocolFee); //compounding the cumulated interest reserves[_reserve].updateCumulativeIndexes(); uint256 totalLiquidityBefore = _availableLiquidityBefore.add(getReserveTotalBorrows(_reserve)); //compounding the received fee into the reserve reserves[_reserve].cumulateToLiquidityIndex(totalLiquidityBefore, _income); //refresh interest rates updateReserveInterestRatesAndTimestampInternal(_reserve, _income, 0); } /** * @dev updates the state of the core as a consequence of a borrow action. * @param _reserve the address of the reserve on which the user is borrowing * @param _user the address of the borrower * @param _amountBorrowed the new amount borrowed * @param _borrowFee the fee on the amount borrowed * @param _rateMode the borrow rate mode (stable, variable) * @return the new borrow rate for the user **/ function updateStateOnBorrow( address _reserve, address _user, uint256 _amountBorrowed, uint256 _borrowFee, CoreLibrary.InterestRateMode _rateMode ) external onlyLendingPool returns (uint256, uint256) { // getting the previous borrow data of the user (uint256 principalBorrowBalance, , uint256 balanceIncrease) = getUserBorrowBalances( _reserve, _user ); updateReserveStateOnBorrowInternal( _reserve, _user, principalBorrowBalance, balanceIncrease, _amountBorrowed, _rateMode ); updateUserStateOnBorrowInternal( _reserve, _user, _amountBorrowed, balanceIncrease, _borrowFee, _rateMode ); updateReserveInterestRatesAndTimestampInternal(_reserve, 0, _amountBorrowed); return (getUserCurrentBorrowRate(_reserve, _user), balanceIncrease); } /** * @dev updates the state of the core as a consequence of a repay action. * @param _reserve the address of the reserve on which the user is repaying * @param _user the address of the borrower * @param _paybackAmountMinusFees the amount being paid back minus fees * @param _originationFeeRepaid the fee on the amount that is being repaid * @param _balanceIncrease the accrued interest on the borrowed amount * @param _repaidWholeLoan true if the user is repaying the whole loan **/ function updateStateOnRepay( address _reserve, address _user, uint256 _paybackAmountMinusFees, uint256 _originationFeeRepaid, uint256 _balanceIncrease, bool _repaidWholeLoan ) external onlyLendingPool { updateReserveStateOnRepayInternal(_reserve, _user, _paybackAmountMinusFees, _balanceIncrease); updateUserStateOnRepayInternal( _reserve, _user, _paybackAmountMinusFees, _originationFeeRepaid, _balanceIncrease, _repaidWholeLoan ); updateReserveInterestRatesAndTimestampInternal(_reserve, _paybackAmountMinusFees, 0); } /** * @dev updates the state of the core as a consequence of a swap rate action. * @param _reserve the address of the reserve on which the user is repaying * @param _user the address of the borrower * @param _principalBorrowBalance the amount borrowed by the user * @param _compoundedBorrowBalance the amount borrowed plus accrued interest * @param _balanceIncrease the accrued interest on the borrowed amount * @param _currentRateMode the current interest rate mode for the user **/ function updateStateOnSwapRate( address _reserve, address _user, uint256 _principalBorrowBalance, uint256 _compoundedBorrowBalance, uint256 _balanceIncrease, CoreLibrary.InterestRateMode _currentRateMode ) external onlyLendingPool returns (CoreLibrary.InterestRateMode, uint256) { updateReserveStateOnSwapRateInternal( _reserve, _user, _principalBorrowBalance, _compoundedBorrowBalance, _currentRateMode ); CoreLibrary.InterestRateMode newRateMode = updateUserStateOnSwapRateInternal( _reserve, _user, _balanceIncrease, _currentRateMode ); updateReserveInterestRatesAndTimestampInternal(_reserve, 0, 0); return (newRateMode, getUserCurrentBorrowRate(_reserve, _user)); } /** * @dev updates the state of the core as a consequence of a liquidation action. * @param _principalReserve the address of the principal reserve that is being repaid * @param _collateralReserve the address of the collateral reserve that is being liquidated * @param _user the address of the borrower * @param _amountToLiquidate the amount being repaid by the liquidator * @param _collateralToLiquidate the amount of collateral being liquidated * @param _feeLiquidated the amount of origination fee being liquidated * @param _liquidatedCollateralForFee the amount of collateral equivalent to the origination fee + bonus * @param _balanceIncrease the accrued interest on the borrowed amount * @param _liquidatorReceivesAToken true if the liquidator will receive aTokens, false otherwise **/ function updateStateOnLiquidation( address _principalReserve, address _collateralReserve, address _user, uint256 _amountToLiquidate, uint256 _collateralToLiquidate, uint256 _feeLiquidated, uint256 _liquidatedCollateralForFee, uint256 _balanceIncrease, bool _liquidatorReceivesAToken ) external onlyLendingPool { updatePrincipalReserveStateOnLiquidationInternal( _principalReserve, _user, _amountToLiquidate, _balanceIncrease ); updateCollateralReserveStateOnLiquidationInternal(_collateralReserve); updateUserStateOnLiquidationInternal( _principalReserve, _user, _amountToLiquidate, _feeLiquidated, _balanceIncrease ); updateReserveInterestRatesAndTimestampInternal(_principalReserve, _amountToLiquidate, 0); if (!_liquidatorReceivesAToken) { updateReserveInterestRatesAndTimestampInternal( _collateralReserve, 0, _collateralToLiquidate.add(_liquidatedCollateralForFee) ); } } /** * @dev updates the state of the core as a consequence of a stable rate rebalance * @param _reserve the address of the principal reserve where the user borrowed * @param _user the address of the borrower * @param _balanceIncrease the accrued interest on the borrowed amount * @return the new stable rate for the user **/ function updateStateOnRebalance( address _reserve, address _user, uint256 _balanceIncrease ) external onlyLendingPool returns (uint256) { updateReserveStateOnRebalanceInternal(_reserve, _user, _balanceIncrease); //update user data and rebalance the rate updateUserStateOnRebalanceInternal(_reserve, _user, _balanceIncrease); updateReserveInterestRatesAndTimestampInternal(_reserve, 0, 0); return usersReserveData[_user][_reserve].stableBorrowRate; } /** * @dev enables or disables a reserve as collateral * @param _reserve the address of the principal reserve where the user deposited * @param _user the address of the depositor * @param _useAsCollateral true if the depositor wants to use the reserve as collateral **/ function setUserUseReserveAsCollateral( address _reserve, address _user, bool _useAsCollateral ) public onlyLendingPool { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; user.useAsCollateral = _useAsCollateral; } /** * @notice ETH/token transfer functions **/ /** * @dev fallback function enforces that the caller is a contract, to support flashloan transfers **/ function() external payable { //only contracts can send ETH to the core require(msg.sender.isContract(), 'Only contracts can send ether to the Lending pool core'); } /** * @dev transfers to the user a specific amount from the reserve. * @param _reserve the address of the reserve where the transfer is happening * @param _user the address of the user receiving the transfer * @param _amount the amount being transferred **/ function transferToUser( address _reserve, address payable _user, uint256 _amount ) external onlyLendingPool { if (_reserve != EthAddressLib.ethAddress()) { ERC20(_reserve).safeTransfer(_user, _amount); } else { //solium-disable-next-line (bool result, ) = _user.call.value(_amount).gas(50000)(''); require(result, 'Transfer of ETH failed'); } } /** * @dev transfers the protocol fees to the fees collection address * @param _token the address of the token being transferred * @param _user the address of the user from where the transfer is happening * @param _amount the amount being transferred * @param _destination the fee receiver address **/ function transferToFeeCollectionAddress( address _token, address _user, uint256 _amount, address _destination ) external payable onlyLendingPool { address payable feeAddress = address(uint160(_destination)); //cast the address to payable if (_token != EthAddressLib.ethAddress()) { require( msg.value == 0, 'User is sending ETH along with the ERC20 transfer. Check the value attribute of the transaction' ); ERC20(_token).safeTransferFrom(_user, feeAddress, _amount); } else { require(msg.value >= _amount, 'The amount and the value sent to deposit do not match'); //solium-disable-next-line (bool result, ) = feeAddress.call.value(_amount).gas(50000)(''); require(result, 'Transfer of ETH failed'); } } /** * @dev transfers the fees to the fees collection address in the case of liquidation * @param _token the address of the token being transferred * @param _amount the amount being transferred * @param _destination the fee receiver address **/ function liquidateFee( address _token, uint256 _amount, address _destination ) external payable onlyLendingPool { address payable feeAddress = address(uint160(_destination)); //cast the address to payable require(msg.value == 0, 'Fee liquidation does not require any transfer of value'); if (_token != EthAddressLib.ethAddress()) { ERC20(_token).safeTransfer(feeAddress, _amount); } else { //solium-disable-next-line (bool result, ) = feeAddress.call.value(_amount).gas(50000)(''); require(result, 'Transfer of ETH failed'); } } /** * @dev transfers an amount from a user to the destination reserve * @param _reserve the address of the reserve where the amount is being transferred * @param _user the address of the user from where the transfer is happening * @param _amount the amount being transferred **/ function transferToReserve( address _reserve, address payable _user, uint256 _amount ) external payable onlyLendingPool { if (_reserve != EthAddressLib.ethAddress()) { require(msg.value == 0, 'User is sending ETH along with the ERC20 transfer.'); ERC20(_reserve).safeTransferFrom(_user, address(this), _amount); } else { require(msg.value >= _amount, 'The amount and the value sent to deposit do not match'); if (msg.value > _amount) { //send back excess ETH uint256 excessAmount = msg.value.sub(_amount); //solium-disable-next-line (bool result, ) = _user.call.value(excessAmount).gas(50000)(''); require(result, 'Transfer of ETH failed'); } } } /** * @notice data access functions **/ /** * @dev returns the basic data (balances, fee accrued, reserve enabled/disabled as collateral) * needed to calculate the global account data in the LendingPoolDataProvider * @param _reserve the address of the reserve * @param _user the address of the user * @return the user deposited balance, the principal borrow balance, the fee, and if the reserve is enabled as collateral or not **/ function getUserBasicReserveData( address _reserve, address _user ) external view returns (uint256, uint256, uint256, bool) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; uint256 underlyingBalance = getUserUnderlyingAssetBalance(_reserve, _user); if (user.principalBorrowBalance == 0) { return (underlyingBalance, 0, 0, user.useAsCollateral); } return ( underlyingBalance, user.getCompoundedBorrowBalance(reserve), user.originationFee, user.useAsCollateral ); } /** * @dev checks if a user is allowed to borrow at a stable rate * @param _reserve the reserve address * @param _user the user * @param _amount the amount the the user wants to borrow * @return true if the user is allowed to borrow at a stable rate, false otherwise **/ function isUserAllowedToBorrowAtStable( address _reserve, address _user, uint256 _amount ) external view returns (bool) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; if (!reserve.isStableBorrowRateEnabled) return false; return !user.useAsCollateral || !reserve.usageAsCollateralEnabled || _amount > getUserUnderlyingAssetBalance(_reserve, _user); } /** * @dev gets the underlying asset balance of a user based on the corresponding aToken balance. * @param _reserve the reserve address * @param _user the user address * @return the underlying deposit balance of the user **/ function getUserUnderlyingAssetBalance( address _reserve, address _user ) public view returns (uint256) { AToken aToken = AToken(reserves[_reserve].aTokenAddress); return aToken.balanceOf(_user); } /** * @dev gets the interest rate strategy contract address for the reserve * @param _reserve the reserve address * @return the address of the interest rate strategy contract **/ function getReserveInterestRateStrategyAddress(address _reserve) public view returns (address) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.interestRateStrategyAddress; } /** * @dev gets the aToken contract address for the reserve * @param _reserve the reserve address * @return the address of the aToken contract **/ function getReserveATokenAddress(address _reserve) public view returns (address) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.aTokenAddress; } /** * @dev gets the available liquidity in the reserve. The available liquidity is the balance of the core contract * @param _reserve the reserve address * @return the available liquidity **/ function getReserveAvailableLiquidity(address _reserve) public view returns (uint256) { uint256 balance = 0; if (_reserve == EthAddressLib.ethAddress()) { balance = address(this).balance; } else { balance = IERC20(_reserve).balanceOf(address(this)); } return balance; } /** * @dev gets the total liquidity in the reserve. The total liquidity is the balance of the core contract + total borrows * @param _reserve the reserve address * @return the total liquidity **/ function getReserveTotalLiquidity(address _reserve) public view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return getReserveAvailableLiquidity(_reserve).add(reserve.getTotalBorrows()); } /** * @dev gets the normalized income of the reserve. a value of 1e27 means there is no income. A value of 2e27 means there * there has been 100% income. * @param _reserve the reserve address * @return the reserve normalized income **/ function getReserveNormalizedIncome(address _reserve) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.getNormalizedIncome(); } /** * @dev gets the reserve total borrows * @param _reserve the reserve address * @return the total borrows (stable + variable) **/ function getReserveTotalBorrows(address _reserve) public view returns (uint256) { return reserves[_reserve].getTotalBorrows(); } /** * @dev gets the reserve total borrows stable * @param _reserve the reserve address * @return the total borrows stable **/ function getReserveTotalBorrowsStable(address _reserve) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.totalBorrowsStable; } /** * @dev gets the reserve total borrows variable * @param _reserve the reserve address * @return the total borrows variable **/ function getReserveTotalBorrowsVariable(address _reserve) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.totalBorrowsVariable; } /** * @dev gets the reserve liquidation threshold * @param _reserve the reserve address * @return the reserve liquidation threshold **/ function getReserveLiquidationThreshold(address _reserve) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.liquidationThreshold; } /** * @dev gets the reserve liquidation bonus * @param _reserve the reserve address * @return the reserve liquidation bonus **/ function getReserveLiquidationBonus(address _reserve) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.liquidationBonus; } /** * @dev gets the reserve current variable borrow rate. Is the base variable borrow rate if the reserve is empty * @param _reserve the reserve address * @return the reserve current variable borrow rate **/ function getReserveCurrentVariableBorrowRate(address _reserve) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; if (reserve.currentVariableBorrowRate == 0) { return IReserveInterestRateStrategy(reserve.interestRateStrategyAddress) .getBaseVariableBorrowRate(); } return reserve.currentVariableBorrowRate; } /** * @dev gets the reserve current stable borrow rate. Is the market rate if the reserve is empty * @param _reserve the reserve address * @return the reserve current stable borrow rate **/ function getReserveCurrentStableBorrowRate(address _reserve) public view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; ILendingRateOracle oracle = ILendingRateOracle(addressesProvider.getLendingRateOracle()); if (reserve.currentStableBorrowRate == 0) { //no stable rate borrows yet return oracle.getMarketBorrowRate(_reserve); } return reserve.currentStableBorrowRate; } /** * @dev gets the reserve average stable borrow rate. The average stable rate is the weighted average * of all the loans taken at stable rate. * @param _reserve the reserve address * @return the reserve current average borrow rate **/ function getReserveCurrentAverageStableBorrowRate( address _reserve ) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.currentAverageStableBorrowRate; } /** * @dev gets the reserve liquidity rate * @param _reserve the reserve address * @return the reserve liquidity rate **/ function getReserveCurrentLiquidityRate(address _reserve) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.currentLiquidityRate; } /** * @dev gets the reserve liquidity cumulative index * @param _reserve the reserve address * @return the reserve liquidity cumulative index **/ function getReserveLiquidityCumulativeIndex(address _reserve) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.lastLiquidityCumulativeIndex; } /** * @dev gets the reserve variable borrow index * @param _reserve the reserve address * @return the reserve variable borrow index **/ function getReserveVariableBorrowsCumulativeIndex( address _reserve ) external view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.lastVariableBorrowCumulativeIndex; } /** * @dev this function aggregates the configuration parameters of the reserve. * It's used in the LendingPoolDataProvider specifically to save gas, and avoid * multiple external contract calls to fetch the same data. * @param _reserve the reserve address * @return the reserve decimals * @return the base ltv as collateral * @return the liquidation threshold * @return if the reserve is used as collateral or not **/ function getReserveConfiguration( address _reserve ) external view returns (uint256, uint256, uint256, bool) { uint256 decimals; uint256 baseLTVasCollateral; uint256 liquidationThreshold; bool usageAsCollateralEnabled; CoreLibrary.ReserveData storage reserve = reserves[_reserve]; decimals = reserve.decimals; baseLTVasCollateral = reserve.baseLTVasCollateral; liquidationThreshold = reserve.liquidationThreshold; usageAsCollateralEnabled = reserve.usageAsCollateralEnabled; return (decimals, baseLTVasCollateral, liquidationThreshold, usageAsCollateralEnabled); } /** * @dev returns the decimals of the reserve * @param _reserve the reserve address * @return the reserve decimals **/ function getReserveDecimals(address _reserve) external view returns (uint256) { return reserves[_reserve].decimals; } /** * @dev returns true if the reserve is enabled for borrowing * @param _reserve the reserve address * @return true if the reserve is enabled for borrowing, false otherwise **/ function isReserveBorrowingEnabled(address _reserve) external view returns (bool) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.borrowingEnabled; } /** * @dev returns true if the reserve is enabled as collateral * @param _reserve the reserve address * @return true if the reserve is enabled as collateral, false otherwise **/ function isReserveUsageAsCollateralEnabled(address _reserve) external view returns (bool) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.usageAsCollateralEnabled; } /** * @dev returns true if the stable rate is enabled on reserve * @param _reserve the reserve address * @return true if the stable rate is enabled on reserve, false otherwise **/ function getReserveIsStableBorrowRateEnabled(address _reserve) external view returns (bool) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.isStableBorrowRateEnabled; } /** * @dev returns true if the reserve is active * @param _reserve the reserve address * @return true if the reserve is active, false otherwise **/ function getReserveIsActive(address _reserve) external view returns (bool) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.isActive; } /** * @notice returns if a reserve is freezed * @param _reserve the reserve for which the information is needed * @return true if the reserve is freezed, false otherwise **/ function getReserveIsFreezed(address _reserve) external view returns (bool) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; return reserve.isFreezed; } /** * @notice returns the timestamp of the last action on the reserve * @param _reserve the reserve for which the information is needed * @return the last updated timestamp of the reserve **/ function getReserveLastUpdate(address _reserve) external view returns (uint40 timestamp) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; timestamp = reserve.lastUpdateTimestamp; } /** * @dev returns the utilization rate U of a specific reserve * @param _reserve the reserve for which the information is needed * @return the utilization rate in ray **/ function getReserveUtilizationRate(address _reserve) public view returns (uint256) { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; uint256 totalBorrows = reserve.getTotalBorrows(); if (totalBorrows == 0) { return 0; } uint256 availableLiquidity = getReserveAvailableLiquidity(_reserve); return totalBorrows.rayDiv(availableLiquidity.add(totalBorrows)); } /** * @return the array of reserves configured on the core **/ function getReserves() external view returns (address[] memory) { return reservesList; } /** * @param _reserve the address of the reserve for which the information is needed * @param _user the address of the user for which the information is needed * @return true if the user has chosen to use the reserve as collateral, false otherwise **/ function isUserUseReserveAsCollateralEnabled( address _reserve, address _user ) external view returns (bool) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; return user.useAsCollateral; } /** * @param _reserve the address of the reserve for which the information is needed * @param _user the address of the user for which the information is needed * @return the origination fee for the user **/ function getUserOriginationFee(address _reserve, address _user) external view returns (uint256) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; return user.originationFee; } /** * @dev users with no loans in progress have NONE as borrow rate mode * @param _reserve the address of the reserve for which the information is needed * @param _user the address of the user for which the information is needed * @return the borrow rate mode for the user, **/ function getUserCurrentBorrowRateMode( address _reserve, address _user ) public view returns (CoreLibrary.InterestRateMode) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; if (user.principalBorrowBalance == 0) { return CoreLibrary.InterestRateMode.NONE; } return user.stableBorrowRate > 0 ? CoreLibrary.InterestRateMode.STABLE : CoreLibrary.InterestRateMode.VARIABLE; } /** * @dev gets the current borrow rate of the user * @param _reserve the address of the reserve for which the information is needed * @param _user the address of the user for which the information is needed * @return the borrow rate for the user, **/ function getUserCurrentBorrowRate( address _reserve, address _user ) internal view returns (uint256) { CoreLibrary.InterestRateMode rateMode = getUserCurrentBorrowRateMode(_reserve, _user); if (rateMode == CoreLibrary.InterestRateMode.NONE) { return 0; } return rateMode == CoreLibrary.InterestRateMode.STABLE ? usersReserveData[_user][_reserve].stableBorrowRate : reserves[_reserve].currentVariableBorrowRate; } /** * @dev the stable rate returned is 0 if the user is borrowing at variable or not borrowing at all * @param _reserve the address of the reserve for which the information is needed * @param _user the address of the user for which the information is needed * @return the user stable rate **/ function getUserCurrentStableBorrowRate( address _reserve, address _user ) external view returns (uint256) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; return user.stableBorrowRate; } /** * @dev calculates and returns the borrow balances of the user * @param _reserve the address of the reserve * @param _user the address of the user * @return the principal borrow balance, the compounded balance and the balance increase since the last borrow/repay/swap/rebalance **/ function getUserBorrowBalances( address _reserve, address _user ) public view returns (uint256, uint256, uint256) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; if (user.principalBorrowBalance == 0) { return (0, 0, 0); } uint256 principal = user.principalBorrowBalance; uint256 compoundedBalance = CoreLibrary.getCompoundedBorrowBalance(user, reserves[_reserve]); return (principal, compoundedBalance, compoundedBalance.sub(principal)); } /** * @dev the variable borrow index of the user is 0 if the user is not borrowing or borrowing at stable * @param _reserve the address of the reserve for which the information is needed * @param _user the address of the user for which the information is needed * @return the variable borrow index for the user **/ function getUserVariableBorrowCumulativeIndex( address _reserve, address _user ) external view returns (uint256) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; return user.lastVariableBorrowCumulativeIndex; } /** * @dev the variable borrow index of the user is 0 if the user is not borrowing or borrowing at stable * @param _reserve the address of the reserve for which the information is needed * @param _user the address of the user for which the information is needed * @return the variable borrow index for the user **/ function getUserLastUpdate( address _reserve, address _user ) external view returns (uint256 timestamp) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; timestamp = user.lastUpdateTimestamp; } /** * @dev updates the lending pool core configuration **/ function refreshConfiguration() external onlyLendingPoolConfigurator { refreshConfigInternal(); } /** * @dev initializes a reserve * @param _reserve the address of the reserve * @param _aTokenAddress the address of the overlying aToken contract * @param _decimals the decimals of the reserve currency * @param _interestRateStrategyAddress the address of the interest rate strategy contract **/ function initReserve( address _reserve, address _aTokenAddress, uint256 _decimals, address _interestRateStrategyAddress ) external onlyLendingPoolConfigurator { reserves[_reserve].init(_aTokenAddress, _decimals, _interestRateStrategyAddress); addReserveToListInternal(_reserve); } /** * @dev removes the last added reserve in the reservesList array * @param _reserveToRemove the address of the reserve **/ function removeLastAddedReserve(address _reserveToRemove) external onlyLendingPoolConfigurator { address lastReserve = reservesList[reservesList.length - 1]; require( lastReserve == _reserveToRemove, 'Reserve being removed is different than the reserve requested' ); //as we can't check if totalLiquidity is 0 (since the reserve added might not be an ERC20) we at least check that there is nothing borrowed require( getReserveTotalBorrows(lastReserve) == 0, 'Cannot remove a reserve with liquidity deposited' ); reserves[lastReserve].isActive = false; reserves[lastReserve].aTokenAddress = address(0); reserves[lastReserve].decimals = 0; reserves[lastReserve].lastLiquidityCumulativeIndex = 0; reserves[lastReserve].lastVariableBorrowCumulativeIndex = 0; reserves[lastReserve].borrowingEnabled = false; reserves[lastReserve].usageAsCollateralEnabled = false; reserves[lastReserve].baseLTVasCollateral = 0; reserves[lastReserve].liquidationThreshold = 0; reserves[lastReserve].liquidationBonus = 0; reserves[lastReserve].interestRateStrategyAddress = address(0); reservesList.pop(); } /** * @dev updates the address of the interest rate strategy contract * @param _reserve the address of the reserve * @param _rateStrategyAddress the address of the interest rate strategy contract **/ function setReserveInterestRateStrategyAddress( address _reserve, address _rateStrategyAddress ) external onlyLendingPoolConfigurator { reserves[_reserve].interestRateStrategyAddress = _rateStrategyAddress; } /** * @dev enables borrowing on a reserve. Also sets the stable rate borrowing * @param _reserve the address of the reserve * @param _stableBorrowRateEnabled true if the stable rate needs to be enabled, false otherwise **/ function enableBorrowingOnReserve( address _reserve, bool _stableBorrowRateEnabled ) external onlyLendingPoolConfigurator { reserves[_reserve].enableBorrowing(_stableBorrowRateEnabled); } /** * @dev disables borrowing on a reserve * @param _reserve the address of the reserve **/ function disableBorrowingOnReserve(address _reserve) external onlyLendingPoolConfigurator { reserves[_reserve].disableBorrowing(); } /** * @dev enables a reserve to be used as collateral * @param _reserve the address of the reserve **/ function enableReserveAsCollateral( address _reserve, uint256 _baseLTVasCollateral, uint256 _liquidationThreshold, uint256 _liquidationBonus ) external onlyLendingPoolConfigurator { reserves[_reserve].enableAsCollateral( _baseLTVasCollateral, _liquidationThreshold, _liquidationBonus ); } /** * @dev disables a reserve to be used as collateral * @param _reserve the address of the reserve **/ function disableReserveAsCollateral(address _reserve) external onlyLendingPoolConfigurator { reserves[_reserve].disableAsCollateral(); } /** * @dev enable the stable borrow rate mode on a reserve * @param _reserve the address of the reserve **/ function enableReserveStableBorrowRate(address _reserve) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.isStableBorrowRateEnabled = true; } /** * @dev disable the stable borrow rate mode on a reserve * @param _reserve the address of the reserve **/ function disableReserveStableBorrowRate(address _reserve) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.isStableBorrowRateEnabled = false; } /** * @dev activates a reserve * @param _reserve the address of the reserve **/ function activateReserve(address _reserve) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; require( reserve.lastLiquidityCumulativeIndex > 0 && reserve.lastVariableBorrowCumulativeIndex > 0, 'Reserve has not been initialized yet' ); reserve.isActive = true; } /** * @dev deactivates a reserve * @param _reserve the address of the reserve **/ function deactivateReserve(address _reserve) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.isActive = false; } /** * @notice allows the configurator to freeze the reserve. * A freezed reserve does not allow any action apart from repay, redeem, liquidationCall, rebalance. * @param _reserve the address of the reserve **/ function freezeReserve(address _reserve) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.isFreezed = true; } /** * @notice allows the configurator to unfreeze the reserve. A unfreezed reserve allows any action to be executed. * @param _reserve the address of the reserve **/ function unfreezeReserve(address _reserve) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.isFreezed = false; } /** * @notice allows the configurator to update the loan to value of a reserve * @param _reserve the address of the reserve * @param _ltv the new loan to value **/ function setReserveBaseLTVasCollateral( address _reserve, uint256 _ltv ) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.baseLTVasCollateral = _ltv; } /** * @notice allows the configurator to update the liquidation threshold of a reserve * @param _reserve the address of the reserve * @param _threshold the new liquidation threshold **/ function setReserveLiquidationThreshold( address _reserve, uint256 _threshold ) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.liquidationThreshold = _threshold; } /** * @notice allows the configurator to update the liquidation bonus of a reserve * @param _reserve the address of the reserve * @param _bonus the new liquidation bonus **/ function setReserveLiquidationBonus( address _reserve, uint256 _bonus ) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.liquidationBonus = _bonus; } /** * @notice allows the configurator to update the reserve decimals * @param _reserve the address of the reserve * @param _decimals the decimals of the reserve **/ function setReserveDecimals( address _reserve, uint256 _decimals ) external onlyLendingPoolConfigurator { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; reserve.decimals = _decimals; } /** * @notice internal functions **/ /** * @dev updates the state of a reserve as a consequence of a borrow action. * @param _reserve the address of the reserve on which the user is borrowing * @param _user the address of the borrower * @param _principalBorrowBalance the previous borrow balance of the borrower before the action * @param _balanceIncrease the accrued interest of the user on the previous borrowed amount * @param _amountBorrowed the new amount borrowed * @param _rateMode the borrow rate mode (stable, variable) **/ function updateReserveStateOnBorrowInternal( address _reserve, address _user, uint256 _principalBorrowBalance, uint256 _balanceIncrease, uint256 _amountBorrowed, CoreLibrary.InterestRateMode _rateMode ) internal { reserves[_reserve].updateCumulativeIndexes(); //increasing reserve total borrows to account for the new borrow balance of the user //NOTE: Depending on the previous borrow mode, the borrows might need to be switched from variable to stable or vice versa updateReserveTotalBorrowsByRateModeInternal( _reserve, _user, _principalBorrowBalance, _balanceIncrease, _amountBorrowed, _rateMode ); } /** * @dev updates the state of a user as a consequence of a borrow action. * @param _reserve the address of the reserve on which the user is borrowing * @param _user the address of the borrower * @param _amountBorrowed the amount borrowed * @param _balanceIncrease the accrued interest of the user on the previous borrowed amount * @param _rateMode the borrow rate mode (stable, variable) * @return the final borrow rate for the user. Emitted by the borrow() event **/ function updateUserStateOnBorrowInternal( address _reserve, address _user, uint256 _amountBorrowed, uint256 _balanceIncrease, uint256 _fee, CoreLibrary.InterestRateMode _rateMode ) internal { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; if (_rateMode == CoreLibrary.InterestRateMode.STABLE) { //stable //reset the user variable index, and update the stable rate user.stableBorrowRate = reserve.currentStableBorrowRate; user.lastVariableBorrowCumulativeIndex = 0; } else if (_rateMode == CoreLibrary.InterestRateMode.VARIABLE) { //variable //reset the user stable rate, and store the new borrow index user.stableBorrowRate = 0; user.lastVariableBorrowCumulativeIndex = reserve.lastVariableBorrowCumulativeIndex; } else { revert('Invalid borrow rate mode'); } //increase the principal borrows and the origination fee user.principalBorrowBalance = user.principalBorrowBalance.add(_amountBorrowed).add( _balanceIncrease ); user.originationFee = user.originationFee.add(_fee); //solium-disable-next-line user.lastUpdateTimestamp = uint40(block.timestamp); } /** * @dev updates the state of the reserve as a consequence of a repay action. * @param _reserve the address of the reserve on which the user is repaying * @param _user the address of the borrower * @param _paybackAmountMinusFees the amount being paid back minus fees * @param _balanceIncrease the accrued interest on the borrowed amount **/ function updateReserveStateOnRepayInternal( address _reserve, address _user, uint256 _paybackAmountMinusFees, uint256 _balanceIncrease ) internal { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; CoreLibrary.UserReserveData storage user = usersReserveData[_reserve][_user]; CoreLibrary.InterestRateMode borrowRateMode = getUserCurrentBorrowRateMode(_reserve, _user); //update the indexes reserves[_reserve].updateCumulativeIndexes(); //compound the cumulated interest to the borrow balance and then subtracting the payback amount if (borrowRateMode == CoreLibrary.InterestRateMode.STABLE) { reserve.increaseTotalBorrowsStableAndUpdateAverageRate( _balanceIncrease, user.stableBorrowRate ); reserve.decreaseTotalBorrowsStableAndUpdateAverageRate( _paybackAmountMinusFees, user.stableBorrowRate ); } else { reserve.increaseTotalBorrowsVariable(_balanceIncrease); reserve.decreaseTotalBorrowsVariable(_paybackAmountMinusFees); } } /** * @dev updates the state of the user as a consequence of a repay action. * @param _reserve the address of the reserve on which the user is repaying * @param _user the address of the borrower * @param _paybackAmountMinusFees the amount being paid back minus fees * @param _originationFeeRepaid the fee on the amount that is being repaid * @param _balanceIncrease the accrued interest on the borrowed amount * @param _repaidWholeLoan true if the user is repaying the whole loan **/ function updateUserStateOnRepayInternal( address _reserve, address _user, uint256 _paybackAmountMinusFees, uint256 _originationFeeRepaid, uint256 _balanceIncrease, bool _repaidWholeLoan ) internal { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; //update the user principal borrow balance, adding the cumulated interest and then subtracting the payback amount user.principalBorrowBalance = user.principalBorrowBalance.add(_balanceIncrease).sub( _paybackAmountMinusFees ); user.lastVariableBorrowCumulativeIndex = reserve.lastVariableBorrowCumulativeIndex; //if the balance decrease is equal to the previous principal (user is repaying the whole loan) //and the rate mode is stable, we reset the interest rate mode of the user if (_repaidWholeLoan) { user.stableBorrowRate = 0; user.lastVariableBorrowCumulativeIndex = 0; } user.originationFee = user.originationFee.sub(_originationFeeRepaid); //solium-disable-next-line user.lastUpdateTimestamp = uint40(block.timestamp); } /** * @dev updates the state of the user as a consequence of a swap rate action. * @param _reserve the address of the reserve on which the user is performing the rate swap * @param _user the address of the borrower * @param _principalBorrowBalance the the principal amount borrowed by the user * @param _compoundedBorrowBalance the principal amount plus the accrued interest * @param _currentRateMode the rate mode at which the user borrowed **/ function updateReserveStateOnSwapRateInternal( address _reserve, address _user, uint256 _principalBorrowBalance, uint256 _compoundedBorrowBalance, CoreLibrary.InterestRateMode _currentRateMode ) internal { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; //compounding reserve indexes reserve.updateCumulativeIndexes(); if (_currentRateMode == CoreLibrary.InterestRateMode.STABLE) { uint256 userCurrentStableRate = user.stableBorrowRate; //swap to variable reserve.decreaseTotalBorrowsStableAndUpdateAverageRate( _principalBorrowBalance, userCurrentStableRate ); //decreasing stable from old principal balance reserve.increaseTotalBorrowsVariable(_compoundedBorrowBalance); //increase variable borrows } else if (_currentRateMode == CoreLibrary.InterestRateMode.VARIABLE) { //swap to stable uint256 currentStableRate = reserve.currentStableBorrowRate; reserve.decreaseTotalBorrowsVariable(_principalBorrowBalance); reserve.increaseTotalBorrowsStableAndUpdateAverageRate( _compoundedBorrowBalance, currentStableRate ); } else { revert('Invalid rate mode received'); } } /** * @dev updates the state of the user as a consequence of a swap rate action. * @param _reserve the address of the reserve on which the user is performing the swap * @param _user the address of the borrower * @param _balanceIncrease the accrued interest on the borrowed amount * @param _currentRateMode the current rate mode of the user **/ function updateUserStateOnSwapRateInternal( address _reserve, address _user, uint256 _balanceIncrease, CoreLibrary.InterestRateMode _currentRateMode ) internal returns (CoreLibrary.InterestRateMode) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; CoreLibrary.ReserveData storage reserve = reserves[_reserve]; CoreLibrary.InterestRateMode newMode = CoreLibrary.InterestRateMode.NONE; if (_currentRateMode == CoreLibrary.InterestRateMode.VARIABLE) { //switch to stable newMode = CoreLibrary.InterestRateMode.STABLE; user.stableBorrowRate = reserve.currentStableBorrowRate; user.lastVariableBorrowCumulativeIndex = 0; } else if (_currentRateMode == CoreLibrary.InterestRateMode.STABLE) { newMode = CoreLibrary.InterestRateMode.VARIABLE; user.stableBorrowRate = 0; user.lastVariableBorrowCumulativeIndex = reserve.lastVariableBorrowCumulativeIndex; } else { revert('Invalid interest rate mode received'); } //compounding cumulated interest user.principalBorrowBalance = user.principalBorrowBalance.add(_balanceIncrease); //solium-disable-next-line user.lastUpdateTimestamp = uint40(block.timestamp); return newMode; } /** * @dev updates the state of the principal reserve as a consequence of a liquidation action. * @param _principalReserve the address of the principal reserve that is being repaid * @param _user the address of the borrower * @param _amountToLiquidate the amount being repaid by the liquidator * @param _balanceIncrease the accrued interest on the borrowed amount **/ function updatePrincipalReserveStateOnLiquidationInternal( address _principalReserve, address _user, uint256 _amountToLiquidate, uint256 _balanceIncrease ) internal { CoreLibrary.ReserveData storage reserve = reserves[_principalReserve]; CoreLibrary.UserReserveData storage user = usersReserveData[_user][_principalReserve]; //update principal reserve data reserve.updateCumulativeIndexes(); CoreLibrary.InterestRateMode borrowRateMode = getUserCurrentBorrowRateMode( _principalReserve, _user ); if (borrowRateMode == CoreLibrary.InterestRateMode.STABLE) { //increase the total borrows by the compounded interest reserve.increaseTotalBorrowsStableAndUpdateAverageRate( _balanceIncrease, user.stableBorrowRate ); //decrease by the actual amount to liquidate reserve.decreaseTotalBorrowsStableAndUpdateAverageRate( _amountToLiquidate, user.stableBorrowRate ); } else { //increase the total borrows by the compounded interest reserve.increaseTotalBorrowsVariable(_balanceIncrease); //decrease by the actual amount to liquidate reserve.decreaseTotalBorrowsVariable(_amountToLiquidate); } } /** * @dev updates the state of the collateral reserve as a consequence of a liquidation action. * @param _collateralReserve the address of the collateral reserve that is being liquidated **/ function updateCollateralReserveStateOnLiquidationInternal(address _collateralReserve) internal { //update collateral reserve reserves[_collateralReserve].updateCumulativeIndexes(); } /** * @dev updates the state of the user being liquidated as a consequence of a liquidation action. * @param _reserve the address of the principal reserve that is being repaid * @param _user the address of the borrower * @param _amountToLiquidate the amount being repaid by the liquidator * @param _feeLiquidated the amount of origination fee being liquidated * @param _balanceIncrease the accrued interest on the borrowed amount **/ function updateUserStateOnLiquidationInternal( address _reserve, address _user, uint256 _amountToLiquidate, uint256 _feeLiquidated, uint256 _balanceIncrease ) internal { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; CoreLibrary.ReserveData storage reserve = reserves[_reserve]; //first increase by the compounded interest, then decrease by the liquidated amount user.principalBorrowBalance = user.principalBorrowBalance.add(_balanceIncrease).sub( _amountToLiquidate ); if (getUserCurrentBorrowRateMode(_reserve, _user) == CoreLibrary.InterestRateMode.VARIABLE) { user.lastVariableBorrowCumulativeIndex = reserve.lastVariableBorrowCumulativeIndex; } if (_feeLiquidated > 0) { user.originationFee = user.originationFee.sub(_feeLiquidated); } //solium-disable-next-line user.lastUpdateTimestamp = uint40(block.timestamp); } /** * @dev updates the state of the reserve as a consequence of a stable rate rebalance * @param _reserve the address of the principal reserve where the user borrowed * @param _user the address of the borrower * @param _balanceIncrease the accrued interest on the borrowed amount **/ function updateReserveStateOnRebalanceInternal( address _reserve, address _user, uint256 _balanceIncrease ) internal { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; reserve.updateCumulativeIndexes(); reserve.increaseTotalBorrowsStableAndUpdateAverageRate(_balanceIncrease, user.stableBorrowRate); } /** * @dev updates the state of the user as a consequence of a stable rate rebalance * @param _reserve the address of the principal reserve where the user borrowed * @param _user the address of the borrower * @param _balanceIncrease the accrued interest on the borrowed amount **/ function updateUserStateOnRebalanceInternal( address _reserve, address _user, uint256 _balanceIncrease ) internal { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; CoreLibrary.ReserveData storage reserve = reserves[_reserve]; user.principalBorrowBalance = user.principalBorrowBalance.add(_balanceIncrease); user.stableBorrowRate = reserve.currentStableBorrowRate; //solium-disable-next-line user.lastUpdateTimestamp = uint40(block.timestamp); } /** * @dev updates the state of the user as a consequence of a stable rate rebalance * @param _reserve the address of the principal reserve where the user borrowed * @param _user the address of the borrower * @param _balanceIncrease the accrued interest on the borrowed amount * @param _amountBorrowed the accrued interest on the borrowed amount **/ function updateReserveTotalBorrowsByRateModeInternal( address _reserve, address _user, uint256 _principalBalance, uint256 _balanceIncrease, uint256 _amountBorrowed, CoreLibrary.InterestRateMode _newBorrowRateMode ) internal { CoreLibrary.InterestRateMode previousRateMode = getUserCurrentBorrowRateMode(_reserve, _user); CoreLibrary.ReserveData storage reserve = reserves[_reserve]; if (previousRateMode == CoreLibrary.InterestRateMode.STABLE) { CoreLibrary.UserReserveData storage user = usersReserveData[_user][_reserve]; reserve.decreaseTotalBorrowsStableAndUpdateAverageRate( _principalBalance, user.stableBorrowRate ); } else if (previousRateMode == CoreLibrary.InterestRateMode.VARIABLE) { reserve.decreaseTotalBorrowsVariable(_principalBalance); } uint256 newPrincipalAmount = _principalBalance.add(_balanceIncrease).add(_amountBorrowed); if (_newBorrowRateMode == CoreLibrary.InterestRateMode.STABLE) { reserve.increaseTotalBorrowsStableAndUpdateAverageRate( newPrincipalAmount, reserve.currentStableBorrowRate ); } else if (_newBorrowRateMode == CoreLibrary.InterestRateMode.VARIABLE) { reserve.increaseTotalBorrowsVariable(newPrincipalAmount); } else { revert('Invalid new borrow rate mode'); } } /** * @dev Updates the reserve current stable borrow rate Rf, the current variable borrow rate Rv and the current liquidity rate Rl. * Also updates the lastUpdateTimestamp value. Please refer to the whitepaper for further information. * @param _reserve the address of the reserve to be updated * @param _liquidityAdded the amount of liquidity added to the protocol (deposit or repay) in the previous action * @param _liquidityTaken the amount of liquidity taken from the protocol (redeem or borrow) **/ function updateReserveInterestRatesAndTimestampInternal( address _reserve, uint256 _liquidityAdded, uint256 _liquidityTaken ) internal { CoreLibrary.ReserveData storage reserve = reserves[_reserve]; ( uint256 newLiquidityRate, uint256 newStableRate, uint256 newVariableRate ) = IReserveInterestRateStrategy(reserve.interestRateStrategyAddress).calculateInterestRates( _reserve, getReserveAvailableLiquidity(_reserve).add(_liquidityAdded).sub(_liquidityTaken), reserve.totalBorrowsStable, reserve.totalBorrowsVariable, reserve.currentAverageStableBorrowRate ); reserve.currentLiquidityRate = newLiquidityRate; reserve.currentStableBorrowRate = newStableRate; reserve.currentVariableBorrowRate = newVariableRate; //solium-disable-next-line reserve.lastUpdateTimestamp = uint40(block.timestamp); emit ReserveUpdated( _reserve, newLiquidityRate, newStableRate, newVariableRate, reserve.lastLiquidityCumulativeIndex, reserve.lastVariableBorrowCumulativeIndex ); } /** * @dev transfers to the protocol fees of a flashloan to the fees collection address * @param _token the address of the token being transferred * @param _amount the amount being transferred **/ function transferFlashLoanProtocolFeeInternal(address _token, uint256 _amount) internal { address payable receiver = address(uint160(addressesProvider.getTokenDistributor())); if (_token != EthAddressLib.ethAddress()) { ERC20(_token).safeTransfer(receiver, _amount); } else { receiver.transfer(_amount); } } /** * @dev updates the internal configuration of the core **/ function refreshConfigInternal() internal { lendingPoolAddress = addressesProvider.getLendingPool(); } /** * @dev adds a reserve to the array of the reserves address **/ function addReserveToListInternal(address _reserve) internal { bool reserveAlreadyAdded = false; for (uint256 i = 0; i < reservesList.length; i++) if (reservesList[i] == _reserve) { reserveAlreadyAdded = true; } if (!reserveAlreadyAdded) reservesList.push(_reserve); } } /** * @title LendingPool contract * @notice Implements the actions of the LendingPool, and exposes accessory methods to fetch the users and reserve data * @author Aave **/ contract LendingPool is ReentrancyGuard, VersionedInitializable { using SafeMath for uint256; using WadRayMath for uint256; using Address for address; LendingPoolAddressesProvider public addressesProvider; LendingPoolCore public core; LendingPoolDataProvider public dataProvider; LendingPoolParametersProvider public parametersProvider; IFeeProvider feeProvider; /** * @dev emitted on deposit * @param _reserve the address of the reserve * @param _user the address of the user * @param _amount the amount to be deposited * @param _referral the referral number of the action * @param _timestamp the timestamp of the action **/ event Deposit( address indexed _reserve, address indexed _user, uint256 _amount, uint16 indexed _referral, uint256 _timestamp ); /** * @dev emitted during a redeem action. * @param _reserve the address of the reserve * @param _user the address of the user * @param _amount the amount to be deposited * @param _timestamp the timestamp of the action **/ event RedeemUnderlying( address indexed _reserve, address indexed _user, uint256 _amount, uint256 _timestamp ); /** * @dev emitted on borrow * @param _reserve the address of the reserve * @param _user the address of the user * @param _amount the amount to be deposited * @param _borrowRateMode the rate mode, can be either 1-stable or 2-variable * @param _borrowRate the rate at which the user has borrowed * @param _originationFee the origination fee to be paid by the user * @param _borrowBalanceIncrease the balance increase since the last borrow, 0 if it's the first time borrowing * @param _referral the referral number of the action * @param _timestamp the timestamp of the action **/ event Borrow( address indexed _reserve, address indexed _user, uint256 _amount, uint256 _borrowRateMode, uint256 _borrowRate, uint256 _originationFee, uint256 _borrowBalanceIncrease, uint16 indexed _referral, uint256 _timestamp ); /** * @dev emitted on repay * @param _reserve the address of the reserve * @param _user the address of the user for which the repay has been executed * @param _repayer the address of the user that has performed the repay action * @param _amountMinusFees the amount repaid minus fees * @param _fees the fees repaid * @param _borrowBalanceIncrease the balance increase since the last action * @param _timestamp the timestamp of the action **/ event Repay( address indexed _reserve, address indexed _user, address indexed _repayer, uint256 _amountMinusFees, uint256 _fees, uint256 _borrowBalanceIncrease, uint256 _timestamp ); /** * @dev emitted when a user performs a rate swap * @param _reserve the address of the reserve * @param _user the address of the user executing the swap * @param _newRateMode the new interest rate mode * @param _newRate the new borrow rate * @param _borrowBalanceIncrease the balance increase since the last action * @param _timestamp the timestamp of the action **/ event Swap( address indexed _reserve, address indexed _user, uint256 _newRateMode, uint256 _newRate, uint256 _borrowBalanceIncrease, uint256 _timestamp ); /** * @dev emitted when a user enables a reserve as collateral * @param _reserve the address of the reserve * @param _user the address of the user **/ event ReserveUsedAsCollateralEnabled(address indexed _reserve, address indexed _user); /** * @dev emitted when a user disables a reserve as collateral * @param _reserve the address of the reserve * @param _user the address of the user **/ event ReserveUsedAsCollateralDisabled(address indexed _reserve, address indexed _user); /** * @dev emitted when the stable rate of a user gets rebalanced * @param _reserve the address of the reserve * @param _user the address of the user for which the rebalance has been executed * @param _newStableRate the new stable borrow rate after the rebalance * @param _borrowBalanceIncrease the balance increase since the last action * @param _timestamp the timestamp of the action **/ event RebalanceStableBorrowRate( address indexed _reserve, address indexed _user, uint256 _newStableRate, uint256 _borrowBalanceIncrease, uint256 _timestamp ); /** * @dev emitted when a flashloan is executed * @param _target the address of the flashLoanReceiver * @param _reserve the address of the reserve * @param _amount the amount requested * @param _totalFee the total fee on the amount * @param _protocolFee the part of the fee for the protocol * @param _timestamp the timestamp of the action **/ event FlashLoan( address indexed _target, address indexed _reserve, uint256 _amount, uint256 _totalFee, uint256 _protocolFee, uint256 _timestamp ); /** * @dev these events are not emitted directly by the LendingPool * but they are declared here as the LendingPoolLiquidationManager * is executed using a delegateCall(). * This allows to have the events in the generated ABI for LendingPool. **/ /** * @dev emitted when a borrow fee is liquidated * @param _collateral the address of the collateral being liquidated * @param _reserve the address of the reserve * @param _user the address of the user being liquidated * @param _feeLiquidated the total fee liquidated * @param _liquidatedCollateralForFee the amount of collateral received by the protocol in exchange for the fee * @param _timestamp the timestamp of the action **/ event OriginationFeeLiquidated( address indexed _collateral, address indexed _reserve, address indexed _user, uint256 _feeLiquidated, uint256 _liquidatedCollateralForFee, uint256 _timestamp ); /** * @dev emitted when a borrower is liquidated * @param _collateral the address of the collateral being liquidated * @param _reserve the address of the reserve * @param _user the address of the user being liquidated * @param _purchaseAmount the total amount liquidated * @param _liquidatedCollateralAmount the amount of collateral being liquidated * @param _accruedBorrowInterest the amount of interest accrued by the borrower since the last action * @param _liquidator the address of the liquidator * @param _receiveAToken true if the liquidator wants to receive aTokens, false otherwise * @param _timestamp the timestamp of the action **/ event LiquidationCall( address indexed _collateral, address indexed _reserve, address indexed _user, uint256 _purchaseAmount, uint256 _liquidatedCollateralAmount, uint256 _accruedBorrowInterest, address _liquidator, bool _receiveAToken, uint256 _timestamp ); /** * @dev functions affected by this modifier can only be invoked by the * aToken.sol contract * @param _reserve the address of the reserve **/ modifier onlyOverlyingAToken(address _reserve) { require( msg.sender == core.getReserveATokenAddress(_reserve), 'The caller of this function can only be the aToken contract of this reserve' ); _; } /** * @dev functions affected by this modifier can only be invoked if the reserve is active * @param _reserve the address of the reserve **/ modifier onlyActiveReserve(address _reserve) { requireReserveActiveInternal(_reserve); _; } /** * @dev functions affected by this modifier can only be invoked if the reserve is not freezed. * A freezed reserve only allows redeems, repays, rebalances and liquidations. * @param _reserve the address of the reserve **/ modifier onlyUnfreezedReserve(address _reserve) { requireReserveNotFreezedInternal(_reserve); _; } /** * @dev functions affected by this modifier can only be invoked if the provided _amount input parameter * is not zero. * @param _amount the amount provided **/ modifier onlyAmountGreaterThanZero(uint256 _amount) { requireAmountGreaterThanZeroInternal(_amount); _; } uint256 public constant UINT_MAX_VALUE = uint256(-1); uint256 public constant LENDINGPOOL_REVISION = 0x2; function getRevision() internal pure returns (uint256) { return LENDINGPOOL_REVISION; } /** * @dev this function is invoked by the proxy contract when the LendingPool contract is added to the * AddressesProvider. * @param _addressesProvider the address of the LendingPoolAddressesProvider registry **/ function initialize(LendingPoolAddressesProvider _addressesProvider) public initializer { addressesProvider = _addressesProvider; core = LendingPoolCore(addressesProvider.getLendingPoolCore()); dataProvider = LendingPoolDataProvider(addressesProvider.getLendingPoolDataProvider()); parametersProvider = LendingPoolParametersProvider( addressesProvider.getLendingPoolParametersProvider() ); feeProvider = IFeeProvider(addressesProvider.getFeeProvider()); } /** * @dev deposits The underlying asset into the reserve. A corresponding amount of the overlying asset (aTokens) * is minted. * @param _reserve the address of the reserve * @param _amount the amount to be deposited * @param _referralCode integrators are assigned a referral code and can potentially receive rewards. **/ function deposit( address _reserve, uint256 _amount, uint16 _referralCode ) external payable nonReentrant onlyActiveReserve(_reserve) onlyUnfreezedReserve(_reserve) onlyAmountGreaterThanZero(_amount) { AToken aToken = AToken(core.getReserveATokenAddress(_reserve)); bool isFirstDeposit = aToken.balanceOf(msg.sender) == 0; core.updateStateOnDeposit(_reserve, msg.sender, _amount, isFirstDeposit); //minting AToken to user 1:1 with the specific exchange rate aToken.mintOnDeposit(msg.sender, _amount); //transfer to the core contract core.transferToReserve.value(msg.value)(_reserve, msg.sender, _amount); //solium-disable-next-line emit Deposit(_reserve, msg.sender, _amount, _referralCode, block.timestamp); } /** * @dev Redeems the underlying amount of assets requested by _user. * This function is executed by the overlying aToken contract in response to a redeem action. * @param _reserve the address of the reserve * @param _user the address of the user performing the action * @param _amount the underlying amount to be redeemed **/ function redeemUnderlying( address _reserve, address payable _user, uint256 _amount, uint256 _aTokenBalanceAfterRedeem ) external nonReentrant onlyOverlyingAToken(_reserve) onlyActiveReserve(_reserve) onlyAmountGreaterThanZero(_amount) { uint256 currentAvailableLiquidity = core.getReserveAvailableLiquidity(_reserve); require( currentAvailableLiquidity >= _amount, 'There is not enough liquidity available to redeem' ); core.updateStateOnRedeem(_reserve, _user, _amount, _aTokenBalanceAfterRedeem == 0); core.transferToUser(_reserve, _user, _amount); //solium-disable-next-line emit RedeemUnderlying(_reserve, _user, _amount, block.timestamp); } /** * @dev data structures for local computations in the borrow() method. */ struct BorrowLocalVars { uint256 principalBorrowBalance; uint256 currentLtv; uint256 currentLiquidationThreshold; uint256 borrowFee; uint256 requestedBorrowAmountETH; uint256 amountOfCollateralNeededETH; uint256 userCollateralBalanceETH; uint256 userBorrowBalanceETH; uint256 userTotalFeesETH; uint256 borrowBalanceIncrease; uint256 currentReserveStableRate; uint256 availableLiquidity; uint256 reserveDecimals; uint256 finalUserBorrowRate; CoreLibrary.InterestRateMode rateMode; bool healthFactorBelowThreshold; } /** * @dev Allows users to borrow a specific amount of the reserve currency, provided that the borrower * already deposited enough collateral. * @param _reserve the address of the reserve * @param _amount the amount to be borrowed * @param _interestRateMode the interest rate mode at which the user wants to borrow. Can be 0 (STABLE) or 1 (VARIABLE) **/ function borrow( address _reserve, uint256 _amount, uint256 _interestRateMode, uint16 _referralCode ) external nonReentrant onlyActiveReserve(_reserve) onlyUnfreezedReserve(_reserve) onlyAmountGreaterThanZero(_amount) { // Usage of a memory struct of vars to avoid "Stack too deep" errors due to local variables BorrowLocalVars memory vars; //check that the reserve is enabled for borrowing require(core.isReserveBorrowingEnabled(_reserve), 'Reserve is not enabled for borrowing'); //validate interest rate mode require( uint256(CoreLibrary.InterestRateMode.VARIABLE) == _interestRateMode || uint256(CoreLibrary.InterestRateMode.STABLE) == _interestRateMode, 'Invalid interest rate mode selected' ); //cast the rateMode to coreLibrary.interestRateMode vars.rateMode = CoreLibrary.InterestRateMode(_interestRateMode); //check that the amount is available in the reserve vars.availableLiquidity = core.getReserveAvailableLiquidity(_reserve); require( vars.availableLiquidity >= _amount, 'There is not enough liquidity available in the reserve' ); ( , vars.userCollateralBalanceETH, vars.userBorrowBalanceETH, vars.userTotalFeesETH, vars.currentLtv, vars.currentLiquidationThreshold, , vars.healthFactorBelowThreshold ) = dataProvider.calculateUserGlobalData(msg.sender); require(vars.userCollateralBalanceETH > 0, 'The collateral balance is 0'); require( !vars.healthFactorBelowThreshold, 'The borrower can already be liquidated so he cannot borrow more' ); //calculating fees vars.borrowFee = feeProvider.calculateLoanOriginationFee(msg.sender, _amount); require(vars.borrowFee > 0, 'The amount to borrow is too small'); vars.amountOfCollateralNeededETH = dataProvider.calculateCollateralNeededInETH( _reserve, _amount, vars.borrowFee, vars.userBorrowBalanceETH, vars.userTotalFeesETH, vars.currentLtv ); require( vars.amountOfCollateralNeededETH <= vars.userCollateralBalanceETH, 'There is not enough collateral to cover a new borrow' ); /** * Following conditions need to be met if the user is borrowing at a stable rate: * 1. Reserve must be enabled for stable rate borrowing * 2. Users cannot borrow from the reserve if their collateral is (mostly) the same currency * they are borrowing, to prevent abuses. * 3. Users will be able to borrow only a relatively small, configurable amount of the total * liquidity **/ if (vars.rateMode == CoreLibrary.InterestRateMode.STABLE) { //check if the borrow mode is stable and if stable rate borrowing is enabled on this reserve require( core.isUserAllowedToBorrowAtStable(_reserve, msg.sender, _amount), 'User cannot borrow the selected amount with a stable rate' ); //calculate the max available loan size in stable rate mode as a percentage of the //available liquidity uint256 maxLoanPercent = parametersProvider.getMaxStableRateBorrowSizePercent(); uint256 maxLoanSizeStable = vars.availableLiquidity.mul(maxLoanPercent).div(100); require( _amount <= maxLoanSizeStable, 'User is trying to borrow too much liquidity at a stable rate' ); } //all conditions passed - borrow is accepted (vars.finalUserBorrowRate, vars.borrowBalanceIncrease) = core.updateStateOnBorrow( _reserve, msg.sender, _amount, vars.borrowFee, vars.rateMode ); //if we reached this point, we can transfer core.transferToUser(_reserve, msg.sender, _amount); emit Borrow( _reserve, msg.sender, _amount, _interestRateMode, vars.finalUserBorrowRate, vars.borrowFee, vars.borrowBalanceIncrease, _referralCode, //solium-disable-next-line block.timestamp ); } /** * @notice repays a borrow on the specific reserve, for the specified amount (or for the whole amount, if uint256(-1) is specified). * @dev the target user is defined by _onBehalfOf. If there is no repayment on behalf of another account, * _onBehalfOf must be equal to msg.sender. * @param _reserve the address of the reserve on which the user borrowed * @param _amount the amount to repay, or uint256(-1) if the user wants to repay everything * @param _onBehalfOf the address for which msg.sender is repaying. **/ struct RepayLocalVars { uint256 principalBorrowBalance; uint256 compoundedBorrowBalance; uint256 borrowBalanceIncrease; bool isETH; uint256 paybackAmount; uint256 paybackAmountMinusFees; uint256 currentStableRate; uint256 originationFee; } function repay( address _reserve, uint256 _amount, address payable _onBehalfOf ) external payable nonReentrant onlyActiveReserve(_reserve) onlyAmountGreaterThanZero(_amount) { // Usage of a memory struct of vars to avoid "Stack too deep" errors due to local variables RepayLocalVars memory vars; (vars.principalBorrowBalance, vars.compoundedBorrowBalance, vars.borrowBalanceIncrease) = core .getUserBorrowBalances(_reserve, _onBehalfOf); vars.originationFee = core.getUserOriginationFee(_reserve, _onBehalfOf); vars.isETH = EthAddressLib.ethAddress() == _reserve; require(vars.compoundedBorrowBalance > 0, 'The user does not have any borrow pending'); require( _amount != UINT_MAX_VALUE || msg.sender == _onBehalfOf, 'To repay on behalf of an user an explicit amount to repay is needed.' ); //default to max amount vars.paybackAmount = vars.compoundedBorrowBalance.add(vars.originationFee); if (_amount != UINT_MAX_VALUE && _amount < vars.paybackAmount) { vars.paybackAmount = _amount; } require( !vars.isETH || msg.value >= vars.paybackAmount, 'Invalid msg.value sent for the repayment' ); //if the amount is smaller than the origination fee, just transfer the amount to the fee destination address if (vars.paybackAmount <= vars.originationFee) { core.updateStateOnRepay( _reserve, _onBehalfOf, 0, vars.paybackAmount, vars.borrowBalanceIncrease, false ); core.transferToFeeCollectionAddress.value(vars.isETH ? vars.paybackAmount : 0)( _reserve, _onBehalfOf, vars.paybackAmount, addressesProvider.getTokenDistributor() ); emit Repay( _reserve, _onBehalfOf, msg.sender, 0, vars.paybackAmount, vars.borrowBalanceIncrease, //solium-disable-next-line block.timestamp ); return; } vars.paybackAmountMinusFees = vars.paybackAmount.sub(vars.originationFee); core.updateStateOnRepay( _reserve, _onBehalfOf, vars.paybackAmountMinusFees, vars.originationFee, vars.borrowBalanceIncrease, vars.compoundedBorrowBalance == vars.paybackAmountMinusFees ); //if the user didn't repay the origination fee, transfer the fee to the fee collection address if (vars.originationFee > 0) { core.transferToFeeCollectionAddress.value(vars.isETH ? vars.originationFee : 0)( _reserve, _onBehalfOf, vars.originationFee, addressesProvider.getTokenDistributor() ); } //sending the total msg.value if the transfer is ETH. //the transferToReserve() function will take care of sending the //excess ETH back to the caller core.transferToReserve.value(vars.isETH ? msg.value.sub(vars.originationFee) : 0)( _reserve, msg.sender, vars.paybackAmountMinusFees ); emit Repay( _reserve, _onBehalfOf, msg.sender, vars.paybackAmountMinusFees, vars.originationFee, vars.borrowBalanceIncrease, //solium-disable-next-line block.timestamp ); } /** * @dev borrowers can user this function to swap between stable and variable borrow rate modes. * @param _reserve the address of the reserve on which the user borrowed **/ function swapBorrowRateMode( address _reserve ) external nonReentrant onlyActiveReserve(_reserve) onlyUnfreezedReserve(_reserve) { ( uint256 principalBorrowBalance, uint256 compoundedBorrowBalance, uint256 borrowBalanceIncrease ) = core.getUserBorrowBalances(_reserve, msg.sender); require(compoundedBorrowBalance > 0, 'User does not have a borrow in progress on this reserve'); CoreLibrary.InterestRateMode currentRateMode = core.getUserCurrentBorrowRateMode( _reserve, msg.sender ); if (currentRateMode == CoreLibrary.InterestRateMode.VARIABLE) { /** * user wants to swap to stable, before swapping we need to ensure that * 1. stable borrow rate is enabled on the reserve * 2. user is not trying to abuse the reserve by depositing * more collateral than he is borrowing, artificially lowering * the interest rate, borrowing at variable, and switching to stable **/ require( core.isUserAllowedToBorrowAtStable(_reserve, msg.sender, compoundedBorrowBalance), 'User cannot borrow the selected amount at stable' ); } (CoreLibrary.InterestRateMode newRateMode, uint256 newBorrowRate) = core.updateStateOnSwapRate( _reserve, msg.sender, principalBorrowBalance, compoundedBorrowBalance, borrowBalanceIncrease, currentRateMode ); emit Swap( _reserve, msg.sender, uint256(newRateMode), newBorrowRate, borrowBalanceIncrease, //solium-disable-next-line block.timestamp ); } /** * @dev rebalances the stable interest rate of a user if current liquidity rate > user stable rate. * this is regulated by Aave to ensure that the protocol is not abused, and the user is paying a fair * rate. Anyone can call this function though. * @param _reserve the address of the reserve * @param _user the address of the user to be rebalanced **/ function rebalanceStableBorrowRate( address _reserve, address _user ) external nonReentrant onlyActiveReserve(_reserve) { (, uint256 compoundedBalance, uint256 borrowBalanceIncrease) = core.getUserBorrowBalances( _reserve, _user ); //step 1: user must be borrowing on _reserve at a stable rate require(compoundedBalance > 0, 'User does not have any borrow for this reserve'); require( core.getUserCurrentBorrowRateMode(_reserve, _user) == CoreLibrary.InterestRateMode.STABLE, 'The user borrow is variable and cannot be rebalanced' ); uint256 userCurrentStableRate = core.getUserCurrentStableBorrowRate(_reserve, _user); uint256 liquidityRate = core.getReserveCurrentLiquidityRate(_reserve); uint256 reserveCurrentStableRate = core.getReserveCurrentStableBorrowRate(_reserve); uint256 rebalanceDownRateThreshold = reserveCurrentStableRate.rayMul( WadRayMath.ray().add(parametersProvider.getRebalanceDownRateDelta()) ); //step 2: we have two possible situations to rebalance: //1. user stable borrow rate is below the current liquidity rate. The loan needs to be rebalanced, //as this situation can be abused (user putting back the borrowed liquidity in the same reserve to earn on it) //2. user stable rate is above the market avg borrow rate of a certain delta, and utilization rate is low. //In this case, the user is paying an interest that is too high, and needs to be rescaled down. if ( userCurrentStableRate < liquidityRate || userCurrentStableRate > rebalanceDownRateThreshold ) { uint256 newStableRate = core.updateStateOnRebalance(_reserve, _user, borrowBalanceIncrease); emit RebalanceStableBorrowRate( _reserve, _user, newStableRate, borrowBalanceIncrease, //solium-disable-next-line block.timestamp ); return; } revert('Interest rate rebalance conditions were not met'); } /** * @dev allows depositors to enable or disable a specific deposit as collateral. * @param _reserve the address of the reserve * @param _useAsCollateral true if the user wants to user the deposit as collateral, false otherwise. **/ function setUserUseReserveAsCollateral( address _reserve, bool _useAsCollateral ) external nonReentrant onlyActiveReserve(_reserve) onlyUnfreezedReserve(_reserve) { uint256 underlyingBalance = core.getUserUnderlyingAssetBalance(_reserve, msg.sender); require(underlyingBalance > 0, 'User does not have any liquidity deposited'); require( dataProvider.balanceDecreaseAllowed(_reserve, msg.sender, underlyingBalance), 'User deposit is already being used as collateral' ); core.setUserUseReserveAsCollateral(_reserve, msg.sender, _useAsCollateral); if (_useAsCollateral) { emit ReserveUsedAsCollateralEnabled(_reserve, msg.sender); } else { emit ReserveUsedAsCollateralDisabled(_reserve, msg.sender); } } /** * @dev users can invoke this function to liquidate an undercollateralized position. * @param _reserve the address of the collateral to liquidated * @param _reserve the address of the principal reserve * @param _user the address of the borrower * @param _purchaseAmount the amount of principal that the liquidator wants to repay * @param _receiveAToken true if the liquidators wants to receive the aTokens, false if * he wants to receive the underlying asset directly **/ function liquidationCall( address _collateral, address _reserve, address _user, uint256 _purchaseAmount, bool _receiveAToken ) external payable nonReentrant onlyActiveReserve(_reserve) onlyActiveReserve(_collateral) { address liquidationManager = addressesProvider.getLendingPoolLiquidationManager(); //solium-disable-next-line (bool success, bytes memory result) = liquidationManager.delegatecall( abi.encodeWithSignature( 'liquidationCall(address,address,address,uint256,bool)', _collateral, _reserve, _user, _purchaseAmount, _receiveAToken ) ); require(success, 'Liquidation call failed'); (uint256 returnCode, string memory returnMessage) = abi.decode(result, (uint256, string)); if (returnCode != 0) { //error found revert(string(abi.encodePacked('Liquidation failed: ', returnMessage))); } } /** * @dev allows smartcontracts to access the liquidity of the pool within one transaction, * as long as the amount taken plus a fee is returned. NOTE There are security concerns for developers of flashloan receiver contracts * that must be kept into consideration. For further details please visit https://developers.aave.com * @param _receiver The address of the contract receiving the funds. The receiver should implement the IFlashLoanReceiver interface. * @param _reserve the address of the principal reserve * @param _amount the amount requested for this flashloan **/ function flashLoan( address _receiver, address _reserve, uint256 _amount, bytes memory _params ) public nonReentrant onlyActiveReserve(_reserve) onlyAmountGreaterThanZero(_amount) { //check that the reserve has enough available liquidity //we avoid using the getAvailableLiquidity() function in LendingPoolCore to save gas uint256 availableLiquidityBefore = _reserve == EthAddressLib.ethAddress() ? address(core).balance : IERC20(_reserve).balanceOf(address(core)); require( availableLiquidityBefore >= _amount, 'There is not enough liquidity available to borrow' ); (uint256 totalFeeBips, uint256 protocolFeeBips) = parametersProvider.getFlashLoanFeesInBips(); //calculate amount fee uint256 amountFee = _amount.mul(totalFeeBips).div(10000); //protocol fee is the part of the amountFee reserved for the protocol - the rest goes to depositors uint256 protocolFee = amountFee.mul(protocolFeeBips).div(10000); require(amountFee > 0 && protocolFee > 0, 'The requested amount is too small for a flashLoan.'); //get the FlashLoanReceiver instance IFlashLoanReceiver receiver = IFlashLoanReceiver(_receiver); address payable userPayable = address(uint160(_receiver)); //transfer funds to the receiver core.transferToUser(_reserve, userPayable, _amount); //execute action of the receiver receiver.executeOperation(_reserve, _amount, amountFee, _params); //check that the actual balance of the core contract includes the returned amount uint256 availableLiquidityAfter = _reserve == EthAddressLib.ethAddress() ? address(core).balance : IERC20(_reserve).balanceOf(address(core)); require( availableLiquidityAfter == availableLiquidityBefore.add(amountFee), 'The actual balance of the protocol is inconsistent' ); core.updateStateOnFlashLoan( _reserve, availableLiquidityBefore, amountFee.sub(protocolFee), protocolFee ); //solium-disable-next-line emit FlashLoan(_receiver, _reserve, _amount, amountFee, protocolFee, block.timestamp); } /** * @dev accessory functions to fetch data from the core contract **/ function getReserveConfigurationData( address _reserve ) external view returns ( uint256 ltv, uint256 liquidationThreshold, uint256 liquidationBonus, address interestRateStrategyAddress, bool usageAsCollateralEnabled, bool borrowingEnabled, bool stableBorrowRateEnabled, bool isActive ) { return dataProvider.getReserveConfigurationData(_reserve); } function getReserveData( address _reserve ) external view returns ( uint256 totalLiquidity, uint256 availableLiquidity, uint256 totalBorrowsStable, uint256 totalBorrowsVariable, uint256 liquidityRate, uint256 variableBorrowRate, uint256 stableBorrowRate, uint256 averageStableBorrowRate, uint256 utilizationRate, uint256 liquidityIndex, uint256 variableBorrowIndex, address aTokenAddress, uint40 lastUpdateTimestamp ) { return dataProvider.getReserveData(_reserve); } function getUserAccountData( address _user ) external view returns ( uint256 totalLiquidityETH, uint256 totalCollateralETH, uint256 totalBorrowsETH, uint256 totalFeesETH, uint256 availableBorrowsETH, uint256 currentLiquidationThreshold, uint256 ltv, uint256 healthFactor ) { return dataProvider.getUserAccountData(_user); } function getUserReserveData( address _reserve, address _user ) external view returns ( uint256 currentATokenBalance, uint256 currentBorrowBalance, uint256 principalBorrowBalance, uint256 borrowRateMode, uint256 borrowRate, uint256 liquidityRate, uint256 originationFee, uint256 variableBorrowIndex, uint256 lastUpdateTimestamp, bool usageAsCollateralEnabled ) { return dataProvider.getUserReserveData(_reserve, _user); } function getReserves() external view returns (address[] memory) { return core.getReserves(); } /** * @dev internal function to save on code size for the onlyActiveReserve modifier **/ function requireReserveActiveInternal(address _reserve) internal view { require(core.getReserveIsActive(_reserve), 'Action requires an active reserve'); } /** * @notice internal function to save on code size for the onlyUnfreezedReserve modifier **/ function requireReserveNotFreezedInternal(address _reserve) internal view { require(!core.getReserveIsFreezed(_reserve), 'Action requires an unfreezed reserve'); } /** * @notice internal function to save on code size for the onlyAmountGreaterThanZero modifier **/ function requireAmountGreaterThanZeroInternal(uint256 _amount) internal pure { require(_amount > 0, 'Amount must be greater than 0'); } } /** * @title LendingPoolLiquidationManager contract * @author Aave * @notice Implements the liquidation function. **/ contract LendingPoolLiquidationManager is ReentrancyGuard, VersionedInitializable { using SafeMath for uint256; using WadRayMath for uint256; using Address for address; LendingPoolAddressesProvider public addressesProvider; LendingPoolCore core; LendingPoolDataProvider dataProvider; LendingPoolParametersProvider parametersProvider; IFeeProvider feeProvider; address ethereumAddress; uint256 constant LIQUIDATION_CLOSE_FACTOR_PERCENT = 50; /** * @dev emitted when a borrow fee is liquidated * @param _collateral the address of the collateral being liquidated * @param _reserve the address of the reserve * @param _user the address of the user being liquidated * @param _feeLiquidated the total fee liquidated * @param _liquidatedCollateralForFee the amount of collateral received by the protocol in exchange for the fee * @param _timestamp the timestamp of the action **/ event OriginationFeeLiquidated( address indexed _collateral, address indexed _reserve, address indexed _user, uint256 _feeLiquidated, uint256 _liquidatedCollateralForFee, uint256 _timestamp ); /** * @dev emitted when a borrower is liquidated * @param _collateral the address of the collateral being liquidated * @param _reserve the address of the reserve * @param _user the address of the user being liquidated * @param _purchaseAmount the total amount liquidated * @param _liquidatedCollateralAmount the amount of collateral being liquidated * @param _accruedBorrowInterest the amount of interest accrued by the borrower since the last action * @param _liquidator the address of the liquidator * @param _receiveAToken true if the liquidator wants to receive aTokens, false otherwise * @param _timestamp the timestamp of the action **/ event LiquidationCall( address indexed _collateral, address indexed _reserve, address indexed _user, uint256 _purchaseAmount, uint256 _liquidatedCollateralAmount, uint256 _accruedBorrowInterest, address _liquidator, bool _receiveAToken, uint256 _timestamp ); enum LiquidationErrors { NO_ERROR, NO_COLLATERAL_AVAILABLE, COLLATERAL_CANNOT_BE_LIQUIDATED, CURRRENCY_NOT_BORROWED, HEALTH_FACTOR_ABOVE_THRESHOLD, NOT_ENOUGH_LIQUIDITY } struct LiquidationCallLocalVars { uint256 userCollateralBalance; uint256 userCompoundedBorrowBalance; uint256 borrowBalanceIncrease; uint256 maxPrincipalAmountToLiquidate; uint256 actualAmountToLiquidate; uint256 liquidationRatio; uint256 collateralPrice; uint256 principalCurrencyPrice; uint256 maxAmountCollateralToLiquidate; uint256 originationFee; uint256 feeLiquidated; uint256 liquidatedCollateralForFee; CoreLibrary.InterestRateMode borrowRateMode; uint256 userStableRate; bool isCollateralEnabled; bool healthFactorBelowThreshold; } /** * @dev as the contract extends the VersionedInitializable contract to match the state * of the LendingPool contract, the getRevision() function is needed. */ function getRevision() internal pure returns (uint256) { return 0; } /** * @dev users can invoke this function to liquidate an undercollateralized position. * @param _reserve the address of the collateral to liquidated * @param _reserve the address of the principal reserve * @param _user the address of the borrower * @param _purchaseAmount the amount of principal that the liquidator wants to repay * @param _receiveAToken true if the liquidators wants to receive the aTokens, false if * he wants to receive the underlying asset directly **/ function liquidationCall( address _collateral, address _reserve, address _user, uint256 _purchaseAmount, bool _receiveAToken ) external payable returns (uint256, string memory) { // Usage of a memory struct of vars to avoid "Stack too deep" errors due to local variables LiquidationCallLocalVars memory vars; (, , , , , , , vars.healthFactorBelowThreshold) = dataProvider.calculateUserGlobalData(_user); if (!vars.healthFactorBelowThreshold) { return ( uint256(LiquidationErrors.HEALTH_FACTOR_ABOVE_THRESHOLD), 'Health factor is not below the threshold' ); } vars.userCollateralBalance = core.getUserUnderlyingAssetBalance(_collateral, _user); //if _user hasn't deposited this specific collateral, nothing can be liquidated if (vars.userCollateralBalance == 0) { return ( uint256(LiquidationErrors.NO_COLLATERAL_AVAILABLE), 'Invalid collateral to liquidate' ); } vars.isCollateralEnabled = core.isReserveUsageAsCollateralEnabled(_collateral) && core.isUserUseReserveAsCollateralEnabled(_collateral, _user); //if _collateral isn't enabled as collateral by _user, it cannot be liquidated if (!vars.isCollateralEnabled) { return ( uint256(LiquidationErrors.COLLATERAL_CANNOT_BE_LIQUIDATED), 'The collateral chosen cannot be liquidated' ); } //if the user hasn't borrowed the specific currency defined by _reserve, it cannot be liquidated (, vars.userCompoundedBorrowBalance, vars.borrowBalanceIncrease) = core.getUserBorrowBalances( _reserve, _user ); if (vars.userCompoundedBorrowBalance == 0) { return ( uint256(LiquidationErrors.CURRRENCY_NOT_BORROWED), 'User did not borrow the specified currency' ); } //all clear - calculate the max principal amount that can be liquidated vars.maxPrincipalAmountToLiquidate = vars .userCompoundedBorrowBalance .mul(LIQUIDATION_CLOSE_FACTOR_PERCENT) .div(100); vars.actualAmountToLiquidate = _purchaseAmount > vars.maxPrincipalAmountToLiquidate ? vars.maxPrincipalAmountToLiquidate : _purchaseAmount; ( uint256 maxCollateralToLiquidate, uint256 principalAmountNeeded ) = calculateAvailableCollateralToLiquidate( _collateral, _reserve, vars.actualAmountToLiquidate, vars.userCollateralBalance ); vars.originationFee = core.getUserOriginationFee(_reserve, _user); //if there is a fee to liquidate, calculate the maximum amount of fee that can be liquidated if (vars.originationFee > 0) { ( vars.liquidatedCollateralForFee, vars.feeLiquidated ) = calculateAvailableCollateralToLiquidate( _collateral, _reserve, vars.originationFee, vars.userCollateralBalance.sub(maxCollateralToLiquidate) ); } //if principalAmountNeeded < vars.ActualAmountToLiquidate, there isn't enough //of _collateral to cover the actual amount that is being liquidated, hence we liquidate //a smaller amount if (principalAmountNeeded < vars.actualAmountToLiquidate) { vars.actualAmountToLiquidate = principalAmountNeeded; } //if liquidator reclaims the underlying asset, we make sure there is enough available collateral in the reserve if (!_receiveAToken) { uint256 currentAvailableCollateral = core.getReserveAvailableLiquidity(_collateral); if (currentAvailableCollateral < maxCollateralToLiquidate) { return ( uint256(LiquidationErrors.NOT_ENOUGH_LIQUIDITY), "There isn't enough liquidity available to liquidate" ); } } core.updateStateOnLiquidation( _reserve, _collateral, _user, vars.actualAmountToLiquidate, maxCollateralToLiquidate, vars.feeLiquidated, vars.liquidatedCollateralForFee, vars.borrowBalanceIncrease, _receiveAToken ); AToken collateralAtoken = AToken(core.getReserveATokenAddress(_collateral)); //if liquidator reclaims the aToken, he receives the equivalent atoken amount if (_receiveAToken) { collateralAtoken.transferOnLiquidation(_user, msg.sender, maxCollateralToLiquidate); } else { //otherwise receives the underlying asset //burn the equivalent amount of atoken collateralAtoken.burnOnLiquidation(_user, maxCollateralToLiquidate); core.transferToUser(_collateral, msg.sender, maxCollateralToLiquidate); } //transfers the principal currency to the pool core.transferToReserve.value(msg.value)(_reserve, msg.sender, vars.actualAmountToLiquidate); if (vars.feeLiquidated > 0) { //if there is enough collateral to liquidate the fee, first transfer burn an equivalent amount of //aTokens of the user collateralAtoken.burnOnLiquidation(_user, vars.liquidatedCollateralForFee); //then liquidate the fee by transferring it to the fee collection address core.liquidateFee( _collateral, vars.liquidatedCollateralForFee, addressesProvider.getTokenDistributor() ); emit OriginationFeeLiquidated( _collateral, _reserve, _user, vars.feeLiquidated, vars.liquidatedCollateralForFee, //solium-disable-next-line block.timestamp ); } emit LiquidationCall( _collateral, _reserve, _user, vars.actualAmountToLiquidate, maxCollateralToLiquidate, vars.borrowBalanceIncrease, msg.sender, _receiveAToken, //solium-disable-next-line block.timestamp ); return (uint256(LiquidationErrors.NO_ERROR), 'No errors'); } struct AvailableCollateralToLiquidateLocalVars { uint256 userCompoundedBorrowBalance; uint256 liquidationBonus; uint256 collateralPrice; uint256 principalCurrencyPrice; uint256 maxAmountCollateralToLiquidate; } /** * @dev calculates how much of a specific collateral can be liquidated, given * a certain amount of principal currency. This function needs to be called after * all the checks to validate the liquidation have been performed, otherwise it might fail. * @param _collateral the collateral to be liquidated * @param _principal the principal currency to be liquidated * @param _purchaseAmount the amount of principal being liquidated * @param _userCollateralBalance the collatera balance for the specific _collateral asset of the user being liquidated * @return the maximum amount that is possible to liquidated given all the liquidation constraints (user balance, close factor) and * the purchase amount **/ function calculateAvailableCollateralToLiquidate( address _collateral, address _principal, uint256 _purchaseAmount, uint256 _userCollateralBalance ) internal view returns (uint256 collateralAmount, uint256 principalAmountNeeded) { collateralAmount = 0; principalAmountNeeded = 0; IPriceOracleGetter oracle = IPriceOracleGetter(addressesProvider.getPriceOracle()); // Usage of a memory struct of vars to avoid "Stack too deep" errors due to local variables AvailableCollateralToLiquidateLocalVars memory vars; vars.collateralPrice = oracle.getAssetPrice(_collateral); vars.principalCurrencyPrice = oracle.getAssetPrice(_principal); vars.liquidationBonus = core.getReserveLiquidationBonus(_collateral); //this is the maximum possible amount of the selected collateral that can be liquidated, given the //max amount of principal currency that is available for liquidation. vars.maxAmountCollateralToLiquidate = vars .principalCurrencyPrice .mul(_purchaseAmount) .div(vars.collateralPrice) .mul(vars.liquidationBonus) .div(100); if (vars.maxAmountCollateralToLiquidate > _userCollateralBalance) { collateralAmount = _userCollateralBalance; principalAmountNeeded = vars .collateralPrice .mul(collateralAmount) .div(vars.principalCurrencyPrice) .mul(100) .div(vars.liquidationBonus); } else { collateralAmount = vars.maxAmountCollateralToLiquidate; principalAmountNeeded = _purchaseAmount; } return (collateralAmount, principalAmountNeeded); } } /** * @title InterestRateStrategyBase contract * @notice implements the base functions needed for the InterestRateStrategy contracts * @author Aave **/ contract DoubleSlopeInterestRateStrategyBase is IReserveInterestRateStrategy { using WadRayMath for uint256; using SafeMath for uint256; LendingPoolAddressesProvider public addressesProvider; //base variable borrow rate when Utilization rate = 0. Expressed in ray uint256 internal baseVariableBorrowRate; //slope of the variable interest curve when utilization rate > 0 and <= OPTIMAL_UTILIZATION_RATE. Expressed in ray uint256 internal variableRateSlope1; //slope of the variable interest curve when utilization rate > OPTIMAL_UTILIZATION_RATE. Expressed in ray uint256 internal variableRateSlope2; //slope of the stable interest curve when utilization rate > 0 and <= OPTIMAL_UTILIZATION_RATE. Expressed in ray uint256 internal stableRateSlope1; //slope of the stable interest curve when utilization rate > OPTIMAL_UTILIZATION_RATE. Expressed in ray uint256 internal stableRateSlope2; constructor( LendingPoolAddressesProvider _provider, uint256 _baseVariableBorrowRate, uint256 _variableRateSlope1, uint256 _variableRateSlope2, uint256 _stableRateSlope1, uint256 _stableRateSlope2 ) public { addressesProvider = _provider; baseVariableBorrowRate = _baseVariableBorrowRate; variableRateSlope1 = _variableRateSlope1; variableRateSlope2 = _variableRateSlope2; stableRateSlope1 = _stableRateSlope1; stableRateSlope2 = _stableRateSlope2; } /** * @dev accessors */ function getVariableRateSlope1() external view returns (uint256) { return variableRateSlope1; } function getVariableRateSlope2() external view returns (uint256) { return variableRateSlope2; } function getStableRateSlope1() external view returns (uint256) { return stableRateSlope1; } function getStableRateSlope2() external view returns (uint256) { return stableRateSlope2; } function getBaseVariableBorrowRate() external view returns (uint256) { return baseVariableBorrowRate; } /** * @dev calculates the liquidity, stable, and variable rates depending on the current utilization rate * and the base parameters * */ function calculateInterestRates( address _reserve, uint256 _utilizationRate, uint256 _totalBorrowsStable, uint256 _totalBorrowsVariable, uint256 _averageStableBorrowRate ) external view returns (uint256 liquidityRate, uint256 stableBorrowRate, uint256 variableBorrowRate); /** * @dev calculates the interest rates depending on the available liquidity and the total borrowed. * @param _reserve the address of the reserve * @param _availableLiquidity the liquidity available in the reserve * @param _totalBorrowsStable the total borrowed from the reserve a stable rate * @param _totalBorrowsVariable the total borrowed from the reserve at a variable rate * @param _averageStableBorrowRate the weighted average of all the stable rate borrows * @param _optimalRatio the optimal target ratio after which slope 2 is used * @return the liquidity rate, stable borrow rate and variable borrow rate calculated from the input parameters **/ function calculateInterestRatesInternal( address _reserve, uint256 _availableLiquidity, uint256 _totalBorrowsStable, uint256 _totalBorrowsVariable, uint256 _averageStableBorrowRate, uint256 _optimalRatio ) internal view returns ( uint256 currentLiquidityRate, uint256 currentStableBorrowRate, uint256 currentVariableBorrowRate ) { uint256 excessRatio = WadRayMath.ray() - _optimalRatio; uint256 totalBorrows = _totalBorrowsStable.add(_totalBorrowsVariable); uint256 utilizationRate = (totalBorrows == 0 && _availableLiquidity == 0) ? 0 : totalBorrows.rayDiv(_availableLiquidity.add(totalBorrows)); currentStableBorrowRate = ILendingRateOracle(addressesProvider.getLendingRateOracle()) .getMarketBorrowRate(_reserve); if (utilizationRate > _optimalRatio) { uint256 excessUtilizationRateRatio = utilizationRate.sub(_optimalRatio).rayDiv(excessRatio); currentStableBorrowRate = currentStableBorrowRate.add(stableRateSlope1).add( stableRateSlope2.rayMul(excessUtilizationRateRatio) ); currentVariableBorrowRate = baseVariableBorrowRate.add(variableRateSlope1).add( variableRateSlope2.rayMul(excessUtilizationRateRatio) ); } else { currentStableBorrowRate = currentStableBorrowRate.add( stableRateSlope1.rayMul(utilizationRate.rayDiv(_optimalRatio)) ); currentVariableBorrowRate = baseVariableBorrowRate.add( utilizationRate.rayDiv(_optimalRatio).rayMul(variableRateSlope1) ); } currentLiquidityRate = getOverallBorrowRateInternal( _totalBorrowsStable, _totalBorrowsVariable, currentVariableBorrowRate, _averageStableBorrowRate ).rayMul(utilizationRate); } /** * @dev calculates the overall borrow rate as the weighted average between the total variable borrows and total stable borrows. * @param _totalBorrowsStable the total borrowed from the reserve a stable rate * @param _totalBorrowsVariable the total borrowed from the reserve at a variable rate * @param _currentVariableBorrowRate the current variable borrow rate * @param _currentAverageStableBorrowRate the weighted average of all the stable rate borrows * @return the weighted averaged borrow rate **/ function getOverallBorrowRateInternal( uint256 _totalBorrowsStable, uint256 _totalBorrowsVariable, uint256 _currentVariableBorrowRate, uint256 _currentAverageStableBorrowRate ) internal pure returns (uint256) { uint256 totalBorrows = _totalBorrowsStable.add(_totalBorrowsVariable); if (totalBorrows == 0) return 0; uint256 weightedVariableRate = _totalBorrowsVariable.wadToRay().rayMul( _currentVariableBorrowRate ); uint256 weightedStableRate = _totalBorrowsStable.wadToRay().rayMul( _currentAverageStableBorrowRate ); uint256 overallBorrowRate = weightedVariableRate.add(weightedStableRate).rayDiv( totalBorrows.wadToRay() ); return overallBorrowRate; } } /** * @title OptimizedReserveInterestRateStrategy contract * @notice implements a double slope interest rate model with 91% optimal threshold. * @author Aave **/ contract OptimizedReserveInterestRateStrategy is DoubleSlopeInterestRateStrategyBase { /** * @dev this constant represents the utilization rate at which the pool aims to obtain most competitive borrow rates * expressed in ray **/ uint256 public constant OPTIMAL_UTILIZATION_RATE = 0.90 * 1e27; constructor( LendingPoolAddressesProvider _provider, uint256 _baseVariableBorrowRate, uint256 _variableRateSlope1, uint256 _variableRateSlope2, uint256 _stableRateSlope1, uint256 _stableRateSlope2 ) public DoubleSlopeInterestRateStrategyBase( _provider, _baseVariableBorrowRate, _variableRateSlope1, _variableRateSlope2, _stableRateSlope1, _stableRateSlope2 ) {} /** * @dev calculates the interest rates depending on the available liquidity and the total borrowed. * @param _reserve the address of the reserve * @param _availableLiquidity the liquidity available in the reserve * @param _totalBorrowsStable the total borrowed from the reserve a stable rate * @param _totalBorrowsVariable the total borrowed from the reserve at a variable rate * @param _averageStableBorrowRate the weighted average of all the stable rate borrows * @return the liquidity rate, stable borrow rate and variable borrow rate calculated from the input parameters **/ function calculateInterestRates( address _reserve, uint256 _availableLiquidity, uint256 _totalBorrowsStable, uint256 _totalBorrowsVariable, uint256 _averageStableBorrowRate ) external view returns ( uint256 currentLiquidityRate, uint256 currentStableBorrowRate, uint256 currentVariableBorrowRate ) { return super.calculateInterestRatesInternal( _reserve, _availableLiquidity, _totalBorrowsStable, _totalBorrowsVariable, _averageStableBorrowRate, OPTIMAL_UTILIZATION_RATE ); } } /** * @title CollateralReserveInterestRateStrategy contract * @notice implements a double slope interest rate model with 45% optimal threshold. * @author Aave **/ contract CollateralReserveInterestRateStrategy is DoubleSlopeInterestRateStrategyBase { /** * @dev this constant represents the utilization rate at which the pool aims to obtain most competitive borrow rates * expressed in ray **/ uint256 public constant OPTIMAL_UTILIZATION_RATE = 0.45 * 1e27; constructor( LendingPoolAddressesProvider _provider, uint256 _baseVariableBorrowRate, uint256 _variableRateSlope1, uint256 _variableRateSlope2, uint256 _stableRateSlope1, uint256 _stableRateSlope2 ) public DoubleSlopeInterestRateStrategyBase( _provider, _baseVariableBorrowRate, _variableRateSlope1, _variableRateSlope2, _stableRateSlope1, _stableRateSlope2 ) {} /** * @dev calculates the interest rates depending on the available liquidity and the total borrowed. * @param _reserve the address of the reserve * @param _availableLiquidity the liquidity available in the reserve * @param _totalBorrowsStable the total borrowed from the reserve a stable rate * @param _totalBorrowsVariable the total borrowed from the reserve at a variable rate * @param _averageStableBorrowRate the weighted average of all the stable rate borrows * @return the liquidity rate, stable borrow rate and variable borrow rate calculated from the input parameters **/ function calculateInterestRates( address _reserve, uint256 _availableLiquidity, uint256 _totalBorrowsStable, uint256 _totalBorrowsVariable, uint256 _averageStableBorrowRate ) external view returns ( uint256 currentLiquidityRate, uint256 currentStableBorrowRate, uint256 currentVariableBorrowRate ) { return (0,0,0); } }
{ "remappings": [ "@aave/core-v3/=lib/aave-address-book/lib/aave-v3-core/", "@aave/periphery-v3/=lib/aave-address-book/lib/aave-v3-periphery/", "aave-address-book/=lib/aave-address-book/src/", "solidity-utils/=lib/solidity-utils/src/", "aave-v3-core/=lib/aave-address-book/lib/aave-v3-core/", "aave-v3-periphery/=lib/aave-address-book/lib/aave-v3-periphery/", "ds-test/=lib/forge-std/lib/ds-test/src/", "forge-std/=lib/forge-std/src/" ], "optimizer": { "enabled": true, "runs": 200 }, "metadata": { "useLiteralContent": false }, "outputSelection": { "*": { "*": [ "evm.bytecode", "evm.deployedBytecode", "devdoc", "userdoc", "metadata", "abi" ] } }, "evmVersion": "istanbul", "libraries": { "src/contracts/UpdatedLendingPool.sol": { "CoreLibrary": "0x57fF2Cbf0D1dfd79b497795B2eDd3B56F1a30397" } } }
Contract Security Audit
- No Contract Security Audit Submitted- Submit Audit Here
[{"inputs":[{"internalType":"contract LendingPoolAddressesProvider","name":"_provider","type":"address"},{"internalType":"uint256","name":"_baseVariableBorrowRate","type":"uint256"},{"internalType":"uint256","name":"_variableRateSlope1","type":"uint256"},{"internalType":"uint256","name":"_variableRateSlope2","type":"uint256"},{"internalType":"uint256","name":"_stableRateSlope1","type":"uint256"},{"internalType":"uint256","name":"_stableRateSlope2","type":"uint256"}],"payable":false,"stateMutability":"nonpayable","type":"constructor"},{"constant":true,"inputs":[],"name":"OPTIMAL_UTILIZATION_RATE","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[],"name":"addressesProvider","outputs":[{"internalType":"contract LendingPoolAddressesProvider","name":"","type":"address"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[{"internalType":"address","name":"_reserve","type":"address"},{"internalType":"uint256","name":"_availableLiquidity","type":"uint256"},{"internalType":"uint256","name":"_totalBorrowsStable","type":"uint256"},{"internalType":"uint256","name":"_totalBorrowsVariable","type":"uint256"},{"internalType":"uint256","name":"_averageStableBorrowRate","type":"uint256"}],"name":"calculateInterestRates","outputs":[{"internalType":"uint256","name":"currentLiquidityRate","type":"uint256"},{"internalType":"uint256","name":"currentStableBorrowRate","type":"uint256"},{"internalType":"uint256","name":"currentVariableBorrowRate","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[],"name":"getBaseVariableBorrowRate","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[],"name":"getStableRateSlope1","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[],"name":"getStableRateSlope2","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[],"name":"getVariableRateSlope1","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[],"name":"getVariableRateSlope2","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"}]
Contract Creation Code
608060405234801561001057600080fd5b50604051610266380380610266833981810160405260c081101561003357600080fd5b508051602082015160408301516060840151608085015160a090950151600080546001600160a01b039096166001600160a01b0319909616959095179094556001929092556002556003556004919091556005556101d0806100966000396000f3fe608060405234801561001057600080fd5b50600436106100885760003560e01c8063a15f30ac1161005b578063a15f30ac14610113578063c72c4d101461011b578063d5cd73911461013f578063f42024091461014757610088565b80630b3429a21461008d57806314e32da4146100a757806334762ca5146100af57806357e37af0146100b7575b600080fd5b61009561014f565b60408051918252519081900360200190f35b610095610155565b61009561015b565b6100f5600480360360a08110156100cd57600080fd5b506001600160a01b038135169060208101359060408101359060608101359060800135610161565b60408051938452602084019290925282820152519081900360600190f35b610095610170565b610123610180565b604080516001600160a01b039092168252519081900360200190f35b61009561018f565b610095610195565b60025490565b60055490565b60015490565b60008080955095509592505050565b6b01743b34e18439b50200000081565b6000546001600160a01b031681565b60045490565b6003549056fea265627a7a723158208c57f10ac99548a868a21236ad99d777841b68aaaf562b1284474320c03d48fb64736f6c6343000511003200000000000000000000000024a42fd28c976a61df5d00d0599c34c4f90748c800000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000
Deployed Bytecode
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
Constructor Arguments (ABI-Encoded and is the last bytes of the Contract Creation Code above)
00000000000000000000000024a42fd28c976a61df5d00d0599c34c4f90748c800000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000
-----Decoded View---------------
Arg [0] : _provider (address): 0x24a42fD28C976A61Df5D00D0599C34c4f90748c8
Arg [1] : _baseVariableBorrowRate (uint256): 0
Arg [2] : _variableRateSlope1 (uint256): 0
Arg [3] : _variableRateSlope2 (uint256): 0
Arg [4] : _stableRateSlope1 (uint256): 0
Arg [5] : _stableRateSlope2 (uint256): 0
-----Encoded View---------------
6 Constructor Arguments found :
Arg [0] : 00000000000000000000000024a42fd28c976a61df5d00d0599c34c4f90748c8
Arg [1] : 0000000000000000000000000000000000000000000000000000000000000000
Arg [2] : 0000000000000000000000000000000000000000000000000000000000000000
Arg [3] : 0000000000000000000000000000000000000000000000000000000000000000
Arg [4] : 0000000000000000000000000000000000000000000000000000000000000000
Arg [5] : 0000000000000000000000000000000000000000000000000000000000000000
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