Overview
Max Total Supply
53,153.883183169297806935 aBUSD
Holders
257 (0.00%)
Total Transfers
-
Market
Price
$1.00 @ 0.000296 ETH (-0.86%)
Onchain Market Cap
$53,119.76
Circulating Supply Market Cap
$0.00
Other Info
Token Contract (WITH 18 Decimals)
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# | Exchange | Pair | Price | 24H Volume | % Volume |
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Similar Match Source Code This contract matches the deployed Bytecode of the Source Code for Contract 0x3a3A65aA...d37d08c04 The constructor portion of the code might be different and could alter the actual behaviour of the contract
Contract Name:
AToken
Compiler Version
v0.5.14+commit.1f1aaa4
Contract Source Code (Solidity)
/** *Submitted for verification at Etherscan.io on 2020-01-10 */ 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 constant private 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); } }
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LendingPoolAddressesProvider","name":"_addressesProvider","type":"address"},{"internalType":"address","name":"_underlyingAsset","type":"address"},{"internalType":"uint8","name":"_underlyingAssetDecimals","type":"uint8"},{"internalType":"string","name":"_name","type":"string"},{"internalType":"string","name":"_symbol","type":"string"}],"payable":false,"stateMutability":"nonpayable","type":"constructor"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"owner","type":"address"},{"indexed":true,"internalType":"address","name":"spender","type":"address"},{"indexed":false,"internalType":"uint256","name":"value","type":"uint256"}],"name":"Approval","type":"event"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"_from","type":"address"},{"indexed":true,"internalType":"address","name":"_to","type":"address"},{"indexed":false,"internalType":"uint256","name":"_value","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromBalanceIncrease","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_toBalanceIncrease","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromIndex","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_toIndex","type":"uint256"}],"name":"BalanceTransfer","type":"event"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"_from","type":"address"},{"indexed":false,"internalType":"uint256","name":"_value","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromBalanceIncrease","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromIndex","type":"uint256"}],"name":"BurnOnLiquidation","type":"event"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"_from","type":"address"},{"indexed":true,"internalType":"address","name":"_to","type":"address"}],"name":"InterestRedirectionAllowanceChanged","type":"event"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"_from","type":"address"},{"indexed":true,"internalType":"address","name":"_to","type":"address"},{"indexed":false,"internalType":"uint256","name":"_redirectedBalance","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromBalanceIncrease","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromIndex","type":"uint256"}],"name":"InterestStreamRedirected","type":"event"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"_from","type":"address"},{"indexed":false,"internalType":"uint256","name":"_value","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromBalanceIncrease","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromIndex","type":"uint256"}],"name":"MintOnDeposit","type":"event"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"_from","type":"address"},{"indexed":false,"internalType":"uint256","name":"_value","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromBalanceIncrease","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_fromIndex","type":"uint256"}],"name":"Redeem","type":"event"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"_targetAddress","type":"address"},{"indexed":false,"internalType":"uint256","name":"_targetBalanceIncrease","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_targetIndex","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_redirectedBalanceAdded","type":"uint256"},{"indexed":false,"internalType":"uint256","name":"_redirectedBalanceRemoved","type":"uint256"}],"name":"RedirectedBalanceUpdated","type":"event"},{"anonymous":false,"inputs":[{"indexed":true,"internalType":"address","name":"from","type":"address"},{"indexed":true,"internalType":"address","name":"to","type":"address"},{"indexed":false,"internalType":"uint256","name":"value","type":"uint256"}],"name":"Transfer","type":"event"},{"constant":true,"inputs":[],"name":"UINT_MAX_VALUE","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"_to","type":"address"}],"name":"allowInterestRedirectionTo","outputs":[],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":true,"inputs":[{"internalType":"address","name":"owner","type":"address"},{"internalType":"address","name":"spender","type":"address"}],"name":"allowance","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"spender","type":"address"},{"internalType":"uint256","name":"value","type":"uint256"}],"name":"approve","outputs":[{"internalType":"bool","name":"","type":"bool"}],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":true,"inputs":[{"internalType":"address","name":"_user","type":"address"}],"name":"balanceOf","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"_account","type":"address"},{"internalType":"uint256","name":"_value","type":"uint256"}],"name":"burnOnLiquidation","outputs":[],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":true,"inputs":[],"name":"decimals","outputs":[{"internalType":"uint8","name":"","type":"uint8"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"spender","type":"address"},{"internalType":"uint256","name":"subtractedValue","type":"uint256"}],"name":"decreaseAllowance","outputs":[{"internalType":"bool","name":"","type":"bool"}],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":true,"inputs":[{"internalType":"address","name":"_user","type":"address"}],"name":"getInterestRedirectionAddress","outputs":[{"internalType":"address","name":"","type":"address"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[{"internalType":"address","name":"_user","type":"address"}],"name":"getRedirectedBalance","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[{"internalType":"address","name":"_user","type":"address"}],"name":"getUserIndex","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"spender","type":"address"},{"internalType":"uint256","name":"addedValue","type":"uint256"}],"name":"increaseAllowance","outputs":[{"internalType":"bool","name":"","type":"bool"}],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":true,"inputs":[{"internalType":"address","name":"_user","type":"address"},{"internalType":"uint256","name":"_amount","type":"uint256"}],"name":"isTransferAllowed","outputs":[{"internalType":"bool","name":"","type":"bool"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"_account","type":"address"},{"internalType":"uint256","name":"_amount","type":"uint256"}],"name":"mintOnDeposit","outputs":[],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":true,"inputs":[],"name":"name","outputs":[{"internalType":"string","name":"","type":"string"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[{"internalType":"address","name":"_user","type":"address"}],"name":"principalBalanceOf","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":false,"inputs":[{"internalType":"uint256","name":"_amount","type":"uint256"}],"name":"redeem","outputs":[],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"_to","type":"address"}],"name":"redirectInterestStream","outputs":[],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"_from","type":"address"},{"internalType":"address","name":"_to","type":"address"}],"name":"redirectInterestStreamOf","outputs":[],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":true,"inputs":[],"name":"symbol","outputs":[{"internalType":"string","name":"","type":"string"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":true,"inputs":[],"name":"totalSupply","outputs":[{"internalType":"uint256","name":"","type":"uint256"}],"payable":false,"stateMutability":"view","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"recipient","type":"address"},{"internalType":"uint256","name":"amount","type":"uint256"}],"name":"transfer","outputs":[{"internalType":"bool","name":"","type":"bool"}],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"sender","type":"address"},{"internalType":"address","name":"recipient","type":"address"},{"internalType":"uint256","name":"amount","type":"uint256"}],"name":"transferFrom","outputs":[{"internalType":"bool","name":"","type":"bool"}],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":false,"inputs":[{"internalType":"address","name":"_from","type":"address"},{"internalType":"address","name":"_to","type":"address"},{"internalType":"uint256","name":"_value","type":"uint256"}],"name":"transferOnLiquidation","outputs":[],"payable":false,"stateMutability":"nonpayable","type":"function"},{"constant":true,"inputs":[],"name":"underlyingAssetAddress","outputs":[{"internalType":"address",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Contract Creation Code
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Swarm Source
bzzr://7029b8e2a8a6dcf81be1753ab59bc1690f3f41e58fae43086d4df87ae569744a
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A token is a representation of an on-chain or off-chain asset. The token page shows information such as price, total supply, holders, transfers and social links. Learn more about this page in our Knowledge Base.