mirror of
https://github.com/tornadocash/tornado-anonymity-mining.git
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96 lines
3.1 KiB
Solidity
96 lines
3.1 KiB
Solidity
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// SPDX-License-Identifier: MIT
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pragma solidity ^0.6.0;
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import "@openzeppelin/contracts/token/ERC20/IERC20.sol";
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import "@openzeppelin/contracts/token/ERC20/SafeERC20.sol";
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import "torn-token/contracts/ENS.sol";
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import "./utils/FloatMath.sol";
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/**
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Let's imagine we have 1M TORN tokens for anonymity mining to distribute during 1 year (~31536000 seconds).
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The contract should constantly add liquidity to a pool of claimed rewards to TORN (REWD/TORN). At any time user can exchange REWD->TORN using
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this pool. The rate depends on current available TORN liquidity - the more TORN are withdrawn the worse the swap rate is.
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The contract starts with some virtual balance liquidity and adds some TORN tokens every second to the balance. Users will decrease
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this balance by swaps.
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Exchange rate can be calculated as following:
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BalanceAfter = BalanceBefore * e^(-rewardAmount/poolWeight)
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tokens = BalanceBefore - BalanceAfter
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*/
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contract RewardSwap is EnsResolve {
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using SafeMath for uint256;
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uint256 public constant DURATION = 365 days;
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IERC20 public immutable torn;
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address public immutable miner;
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uint256 public immutable startTimestamp;
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uint256 public immutable initialLiquidity;
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uint256 public immutable liquidity;
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uint256 public tokensSold;
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uint256 public poolWeight;
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event Swap(address indexed recipient, uint256 pTORN, uint256 TORN);
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event PoolWeightUpdated(uint256 newWeight);
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modifier onlyMiner() {
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require(msg.sender == miner, "Only Miner contract can call");
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_;
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}
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constructor(
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bytes32 _torn,
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bytes32 _miner,
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uint256 _miningCap,
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uint256 _initialLiquidity,
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uint256 _poolWeight
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) public {
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require(_initialLiquidity <= _miningCap, "Initial liquidity should be lower than mining cap");
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torn = IERC20(resolve(_torn));
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miner = resolve(_miner);
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initialLiquidity = _initialLiquidity;
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liquidity = _miningCap.sub(_initialLiquidity);
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poolWeight = _poolWeight;
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startTimestamp = getTimestamp();
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}
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function swap(address _recipient, uint256 _amount) external onlyMiner returns (uint256) {
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uint256 tokens = getExpectedReturn(_amount);
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tokensSold += tokens;
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require(torn.transfer(_recipient, tokens), "transfer failed");
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emit Swap(_recipient, _amount, tokens);
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return tokens;
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}
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/**
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@dev
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*/
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function getExpectedReturn(uint256 _amount) public view returns (uint256) {
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uint256 oldBalance = tornVirtualBalance();
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int128 pow = FloatMath.neg(FloatMath.divu(_amount, poolWeight));
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int128 exp = FloatMath.exp(pow);
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uint256 newBalance = FloatMath.mulu(exp, oldBalance);
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return oldBalance.sub(newBalance);
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}
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function tornVirtualBalance() public view returns (uint256) {
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uint256 passedTime = getTimestamp().sub(startTimestamp);
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if (passedTime < DURATION) {
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return initialLiquidity.add(liquidity.mul(passedTime).div(DURATION)).sub(tokensSold);
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} else {
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return torn.balanceOf(address(this));
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}
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}
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function setPoolWeight(uint256 _newWeight) external onlyMiner {
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poolWeight = _newWeight;
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emit PoolWeightUpdated(_newWeight);
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}
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function getTimestamp() public view virtual returns (uint256) {
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return block.timestamp;
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}
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}
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