erc20-demurrage-token/solidity/DemurrageTokenMultiNocap.sol

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pragma solidity > 0.6.11;
// SPDX-License-Identifier: GPL-3.0-or-later
contract DemurrageTokenMultiNocap {
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// Redistribution bit field, with associated shifts and masks
// (Uses sub-byte boundaries)
bytes32[] public redistributions; // uint1(isFractional) | uint95(unused) | uint20(demurrageModifier) | uint36(participants) | uint72(value) | uint32(period)
uint8 constant shiftRedistributionPeriod = 0;
uint256 constant maskRedistributionPeriod = 0x00000000000000000000000000000000000000000000000000000000ffffffff; // (1 << 32) - 1
uint8 constant shiftRedistributionValue = 32;
uint256 constant maskRedistributionValue = 0x00000000000000000000000000000000000000ffffffffffffffffff00000000; // ((1 << 72) - 1) << 32
uint8 constant shiftRedistributionParticipants = 104;
uint256 constant maskRedistributionParticipants = 0x00000000000000000000000000000fffffffff00000000000000000000000000; // ((1 << 36) - 1) << 104
uint8 constant shiftRedistributionDemurrage = 140;
uint256 constant maskRedistributionDemurrage = 0x000000000000000000000000fffff00000000000000000000000000000000000; // ((1 << 20) - 1) << 140
uint8 constant shiftRedistributionIsFractional = 255;
uint256 constant maskRedistributionIsFractional = 0x8000000000000000000000000000000000000000000000000000000000000000; // 1 << 255
// Account bit field, with associated shifts and masks
// Mirrors structure of redistributions for consistency
mapping (address => bytes32) account; // uint152(unused) | uint32(period) | uint72(value)
uint8 constant shiftAccountValue = 0;
uint256 constant maskAccountValue = 0x0000000000000000000000000000000000000000000000ffffffffffffffffff; // (1 << 72) - 1
uint8 constant shiftAccountPeriod = 72;
uint256 constant maskAccountPeriod = 0x00000000000000000000000000000000000000ffffffff000000000000000000; // ((1 << 32) - 1) << 72
// Cached demurrage amount, ppm with 38 digit resolution
uint128 public demurrageAmount;
// Cached demurrage period; the period for which demurrageAmount was calculated
uint128 public demurragePeriod;
// Implements EIP172
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address public owner;
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address newOwner;
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// Implements ERC20
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string public name;
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// Implements ERC20
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string public symbol;
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// Implements ERC20
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uint256 public decimals;
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// Implements ERC20
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uint256 public totalSupply;
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// Minimum amount of (demurraged) tokens an account must spend to participate in redistribution for a particular period
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uint256 public minimumParticipantSpend;
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// 128 bit resolution of the demurrage divisor
// (this constant x 1000000 is contained within 128 bits)
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uint256 constant ppmDivider = 100000000000000000000000000000000;
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// demurrage decimal width; 38 places
uint256 public immutable resolutionFactor = ppmDivider * 1000000;
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// Timestamp of start of periods (time which contract constructor was called)
uint256 public immutable periodStart;
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// Duration of a single redistribution period in seconds
uint256 public immutable periodDuration;
// Demurrage in ppm per minute
uint256 public immutable taxLevel;
// Addresses allowed to mint new tokens
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mapping (address => bool) minter;
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// Storage for ERC20 approve/transferFrom methods
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mapping (address => mapping (address => uint256 ) ) allowance; // holder -> spender -> amount (amount is subject to demurrage)
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// Address to send unallocated redistribution tokens
address sinkAddress;
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// Implements ERC20
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event Transfer(address indexed _from, address indexed _to, uint256 _value);
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// Implements ERC20
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event Approval(address indexed _owner, address indexed _spender, uint256 _value);
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// New tokens minted
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event Mint(address indexed _minter, address indexed _beneficiary, uint256 _value);
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// New demurrage cache milestone calculated
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event Decayed(uint256 indexed _period, uint256 indexed _periodCount, uint256 indexed _oldAmount, uint256 _newAmount);
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// When a new period threshold has been crossed
event Period(uint256 _period);
// Redistribution applied on a single eligible account
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event Redistribution(address indexed _account, uint256 indexed _period, uint256 _value);
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// Temporary event used in development, will be removed on prod
event Debug(bytes32 _foo);
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// EIP173
event OwnershipTransferred(address indexed previousOwner, address indexed newOwner); // EIP173
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constructor(string memory _name, string memory _symbol, uint8 _decimals, uint256 _taxLevelMinute, uint256 _periodMinutes, address _defaultSinkAddress) public {
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// ACL setup
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owner = msg.sender;
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minter[owner] = true;
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// ERC20 setup
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name = _name;
symbol = _symbol;
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decimals = _decimals;
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// Demurrage setup
periodStart = block.timestamp;
periodDuration = _periodMinutes * 60;
demurrageAmount = uint128(ppmDivider * 1000000); // Represents 38 decimal places
demurragePeriod = 1;
taxLevel = _taxLevelMinute; // Represents 38 decimal places
bytes32 initialRedistribution = toRedistribution(0, 1000000, 0, 1);
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redistributions.push(initialRedistribution);
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// Misc settings
sinkAddress = _defaultSinkAddress;
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minimumParticipantSpend = 10 ** uint256(_decimals);
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}
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// Given address will be allowed to call the mintTo() function
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function addMinter(address _minter) public returns (bool) {
require(msg.sender == owner);
minter[_minter] = true;
return true;
}
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// Given address will no longer be allowed to call the mintTo() function
function removeMinter(address _minter) public returns (bool) {
require(msg.sender == owner || _minter == msg.sender);
minter[_minter] = false;
return true;
}
/// Implements ERC20
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function balanceOf(address _account) public view returns (uint256) {
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uint256 baseBalance;
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uint256 currentDemurragedAmount;
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uint256 periodCount;
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baseBalance = baseBalanceOf(_account);
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periodCount = actualPeriod() - demurragePeriod;
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currentDemurragedAmount = uint128(decayBy(demurrageAmount, periodCount));
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return (baseBalance * currentDemurragedAmount) / (ppmDivider * 1000000);
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}
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/// Balance unmodified by demurrage
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function baseBalanceOf(address _account) public view returns (uint256) {
return uint256(account[_account]) & maskAccountValue;
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}
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/// Increases base balance for a single account
function increaseBaseBalance(address _account, uint256 _delta) private returns (bool) {
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uint256 oldBalance;
uint256 newBalance;
uint256 workAccount;
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workAccount = uint256(account[_account]);
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if (_delta == 0) {
return false;
}
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oldBalance = baseBalanceOf(_account);
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newBalance = oldBalance + _delta;
require(uint160(newBalance) > uint160(oldBalance), 'ERR_WOULDWRAP'); // revert if increase would result in a wrapped value
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workAccount &= (~maskAccountValue);
workAccount |= (newBalance & maskAccountValue);
account[_account] = bytes32(workAccount);
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return true;
}
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/// Decreases base balance for a single account
function decreaseBaseBalance(address _account, uint256 _delta) private returns (bool) {
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uint256 oldBalance;
uint256 newBalance;
uint256 workAccount;
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workAccount = uint256(account[_account]);
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if (_delta == 0) {
return false;
}
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oldBalance = baseBalanceOf(_account);
require(oldBalance >= _delta, 'ERR_OVERSPEND'); // overspend guard
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newBalance = oldBalance - _delta;
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workAccount &= (~maskAccountValue);
workAccount |= (newBalance & maskAccountValue);
account[_account] = bytes32(workAccount);
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return true;
}
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// Creates new tokens out of thin air, and allocates them to the given address
// Triggers tax
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function mintTo(address _beneficiary, uint256 _amount) external returns (bool) {
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uint256 baseAmount;
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require(minter[msg.sender]);
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changePeriod();
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baseAmount = _amount;
totalSupply += _amount;
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increaseBaseBalance(_beneficiary, baseAmount);
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emit Mint(msg.sender, _beneficiary, _amount);
saveRedistributionSupply();
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return true;
}
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// Deserializes the redistribution word
// uint1(isFractional) | uint95(unused) | uint20(demurrageModifier) | uint36(participants) | uint72(value) | uint32(period)
function toRedistribution(uint256 _participants, uint256 _demurrageModifierPpm, uint256 _value, uint256 _period) private pure returns(bytes32) {
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bytes32 redistribution;
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redistribution |= bytes32((_demurrageModifierPpm << shiftRedistributionDemurrage) & maskRedistributionDemurrage);
redistribution |= bytes32((_participants << shiftRedistributionParticipants) & maskRedistributionParticipants);
redistribution |= bytes32((_value << shiftRedistributionValue) & maskRedistributionValue);
redistribution |= bytes32(_period & maskRedistributionPeriod);
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return redistribution;
}
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// Serializes the demurrage period part of the redistribution word
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function toRedistributionPeriod(bytes32 redistribution) public pure returns (uint256) {
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return uint256(redistribution) & maskRedistributionPeriod;
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}
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// Serializes the supply part of the redistribution word
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function toRedistributionSupply(bytes32 redistribution) public pure returns (uint256) {
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return (uint256(redistribution) & maskRedistributionValue) >> shiftRedistributionValue;
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}
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// Serializes the number of participants part of the redistribution word
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function toRedistributionParticipants(bytes32 redistribution) public pure returns (uint256) {
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return (uint256(redistribution) & maskRedistributionParticipants) >> shiftRedistributionParticipants;
}
// Serializes the number of participants part of the redistribution word
function toRedistributionDemurrageModifier(bytes32 redistribution) public pure returns (uint256) {
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return (uint256(redistribution) & maskRedistributionDemurrage) >> shiftRedistributionDemurrage;
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}
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// Client accessor to the redistributions array length
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function redistributionCount() public view returns (uint256) {
return redistributions.length;
}
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// Add number of participants for the current redistribution period by one
function incrementRedistributionParticipants() private returns (bool) {
bytes32 currentRedistribution;
uint256 tmpRedistribution;
uint256 participants;
currentRedistribution = redistributions[redistributions.length-1];
participants = toRedistributionParticipants(currentRedistribution) + 1;
tmpRedistribution = uint256(currentRedistribution);
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tmpRedistribution &= (~maskRedistributionParticipants);
tmpRedistribution |= ((participants << shiftRedistributionParticipants) & maskRedistributionParticipants);
redistributions[redistributions.length-1] = bytes32(tmpRedistribution);
return true;
}
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// Save the current total supply amount to the current redistribution period
function saveRedistributionSupply() private returns (bool) {
uint256 currentRedistribution;
currentRedistribution = uint256(redistributions[redistributions.length-1]);
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currentRedistribution &= (~maskRedistributionValue);
currentRedistribution |= (totalSupply << shiftRedistributionValue);
redistributions[redistributions.length-1] = bytes32(currentRedistribution);
return true;
}
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// Get the demurrage period of the current block number
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function actualPeriod() public view returns (uint128) {
return uint128((block.timestamp - periodStart) / periodDuration + 1);
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}
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// Add an entered demurrage period to the redistribution array
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function checkPeriod() private view returns (bytes32) {
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bytes32 lastRedistribution;
uint256 currentPeriod;
lastRedistribution = redistributions[redistributions.length-1];
currentPeriod = this.actualPeriod();
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if (currentPeriod <= toRedistributionPeriod(lastRedistribution)) {
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return bytes32(0x00);
}
return lastRedistribution;
}
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// Deserialize the pemurrage period for the given account is participating in
function accountPeriod(address _account) public view returns (uint256) {
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return (uint256(account[_account]) & maskAccountPeriod) >> shiftAccountPeriod;
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}
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// Save the given demurrage period as the currently participation period for the given address
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function registerAccountPeriod(address _account, uint256 _period) private returns (bool) {
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account[_account] &= bytes32(~maskAccountPeriod);
account[_account] |= bytes32((_period << shiftAccountPeriod) & maskAccountPeriod);
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incrementRedistributionParticipants();
return true;
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}
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// Determine whether the unit number is rounded down, rounded up or evenly divides.
// Returns 0 if evenly distributed, or the remainder as a positive number
// A _numParts value 0 will be interpreted as the value 1
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function remainder(uint256 _numParts, uint256 _sumWhole) public pure returns (uint256) {
uint256 unit;
uint256 truncatedResult;
if (_numParts == 0) { // no division by zero please
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revert('ERR_NUMPARTS_ZERO');
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}
require(_numParts < _sumWhole); // At least you are never LESS than the sum of your parts. Think about that.
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unit = _sumWhole / _numParts;
truncatedResult = unit * _numParts;
return _sumWhole - truncatedResult;
}
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// Called in the edge case where participant number is 0. It will override the participant count to 1.
// Returns the remainder sent to the sink address
function applyDefaultRedistribution(bytes32 _redistribution) private returns (uint256) {
uint256 redistributionSupply;
uint256 redistributionPeriod;
uint256 unit;
uint256 truncatedResult;
redistributionSupply = toRedistributionSupply(_redistribution);
unit = (redistributionSupply * taxLevel) / 1000000;
truncatedResult = (unit * 1000000) / taxLevel;
if (truncatedResult < redistributionSupply) {
redistributionPeriod = toRedistributionPeriod(_redistribution); // since we reuse period here, can possibly be optimized by passing period instead
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redistributions[redistributionPeriod-1] &= bytes32(~maskRedistributionParticipants); // just to be safe, zero out all participant count data, in this case there will be only one
redistributions[redistributionPeriod-1] |= bytes32(maskRedistributionIsFractional | (1 << shiftRedistributionParticipants));
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}
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increaseBaseBalance(sinkAddress, unit / ppmDivider);
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return unit;
}
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// sets the remainder bit for the given period and books the remainder to the sink address balance
// returns false if no change was made
function applyRemainderOnPeriod(uint256 _remainder, uint256 _period) private returns (bool) {
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uint256 periodSupply;
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if (_remainder == 0) {
return false;
}
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// TODO: is this needed?
redistributions[_period-1] |= bytes32(maskRedistributionIsFractional);
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periodSupply = toRedistributionSupply(redistributions[_period-1]);
increaseBaseBalance(sinkAddress, periodSupply - _remainder);
return true;
}
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// Calculate and cache the demurrage value corresponding to the (period of the) time of the method call
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function applyDemurrage() public returns (bool) {
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uint128 epochPeriodCount;
uint128 periodCount;
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uint256 lastDemurrageAmount;
uint256 newDemurrageAmount;
epochPeriodCount = actualPeriod();
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periodCount = epochPeriodCount - demurragePeriod;
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if (periodCount == 0) {
return false;
}
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lastDemurrageAmount = demurrageAmount;
demurrageAmount = uint128(decayBy(lastDemurrageAmount, periodCount));
demurragePeriod = epochPeriodCount;
emit Decayed(epochPeriodCount, periodCount, lastDemurrageAmount, demurrageAmount);
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return true;
}
// Return timestamp of start of period threshold
function getPeriodTimeDelta(uint256 _periodCount) public view returns (uint256) {
return periodStart + (_periodCount * periodDuration);
}
// Amount of demurrage cycles inbetween the current timestamp and the given target time
function demurrageCycles(uint256 _target) public view returns (uint256) {
return (block.timestamp - _target) / 60;
}
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// Recalculate the demurrage modifier for the new period
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// After this, all REPORTED balances will have been reduced by the corresponding ratio (but the effecive totalsupply stays the same)
function changePeriod() public returns (bool) {
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bytes32 currentRedistribution;
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bytes32 nextRedistribution;
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uint256 currentPeriod;
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uint256 currentParticipants;
uint256 currentRemainder;
uint256 currentDemurrageAmount;
uint256 nextRedistributionDemurrage;
uint256 demurrageCounts;
uint256 periodTimestamp;
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uint256 nextPeriod;
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currentRedistribution = checkPeriod();
if (currentRedistribution == bytes32(0x00)) {
return false;
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}
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currentPeriod = toRedistributionPeriod(currentRedistribution);
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nextPeriod = currentPeriod + 1;
periodTimestamp = getPeriodTimeDelta(currentPeriod);
applyDemurrage();
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currentDemurrageAmount = demurrageAmount;
demurrageCounts = demurrageCycles(periodTimestamp);
if (demurrageCounts > 0) {
nextRedistributionDemurrage = growBy(currentDemurrageAmount, demurrageCounts) / ppmDivider;
} else {
nextRedistributionDemurrage = currentDemurrageAmount / ppmDivider;
}
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nextRedistribution = toRedistribution(0, nextRedistributionDemurrage, totalSupply, nextPeriod);
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redistributions.push(nextRedistribution);
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currentParticipants = toRedistributionParticipants(currentRedistribution);
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if (currentParticipants == 0) {
currentRemainder = applyDefaultRedistribution(currentRedistribution);
} else {
currentRemainder = remainder(currentParticipants, totalSupply); // we can use totalSupply directly because it will always be the same as the recorded supply on the current redistribution
applyRemainderOnPeriod(currentRemainder, currentPeriod);
}
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emit Period(nextPeriod);
return true;
}
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// Reverse a value reduced by demurrage by the given period to its original value
function growBy(uint256 _value, uint256 _period) public view returns (uint256) {
uint256 valueFactor;
uint256 truncatedTaxLevel;
valueFactor = 1000000;
truncatedTaxLevel = taxLevel / ppmDivider;
for (uint256 i = 0; i < _period; i++) {
valueFactor = valueFactor + ((valueFactor * truncatedTaxLevel) / 1000000);
}
return (valueFactor * _value) / 1000000;
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}
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// Calculate a value reduced by demurrage by the given period
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// TODO: higher precision if possible
function decayBy(uint256 _value, uint256 _period) public view returns (uint256) {
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uint256 valueFactor;
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uint256 truncatedTaxLevel;
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valueFactor = 1000000;
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truncatedTaxLevel = taxLevel / ppmDivider;
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for (uint256 i = 0; i < _period; i++) {
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valueFactor = valueFactor - ((valueFactor * truncatedTaxLevel) / 1000000);
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}
return (valueFactor * _value) / 1000000;
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}
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// If the given account is participating in a period and that period has been crossed
// THEN increase the base value of the account with its share of the value reduction of the period
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function applyRedistributionOnAccount(address _account) public returns (bool) {
bytes32 periodRedistribution;
uint256 supply;
uint256 participants;
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uint256 baseValue;
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uint256 value;
uint256 period;
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uint256 demurrage;
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period = accountPeriod(_account);
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if (period == 0 || period >= actualPeriod()) {
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return false;
}
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periodRedistribution = redistributions[period-1];
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participants = toRedistributionParticipants(periodRedistribution);
if (participants == 0) {
return false;
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}
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supply = toRedistributionSupply(periodRedistribution);
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demurrage = toRedistributionDemurrageModifier(periodRedistribution);
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baseValue = ((supply / participants) * (taxLevel / 1000000)) / ppmDivider;
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value = (baseValue * demurrage) / 1000000;
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// zero out period for the account
account[_account] &= bytes32(~maskAccountPeriod);
increaseBaseBalance(_account, value);
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emit Redistribution(_account, period, value);
return true;
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}
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// Inflates the given amount according to the current demurrage modifier
function toBaseAmount(uint256 _value) public view returns (uint256) {
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//return (_value * ppmDivider * 1000000) / toDemurrageAmount(demurrageModifier);
return (_value * ppmDivider * 1000000) / demurrageAmount;
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}
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// Implements ERC20, triggers tax and/or redistribution
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function approve(address _spender, uint256 _value) public returns (bool) {
uint256 baseValue;
changePeriod();
applyRedistributionOnAccount(msg.sender);
baseValue = toBaseAmount(_value);
allowance[msg.sender][_spender] += baseValue;
emit Approval(msg.sender, _spender, _value);
return true;
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}
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// Implements ERC20, triggers tax and/or redistribution
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function transfer(address _to, uint256 _value) public returns (bool) {
uint256 baseValue;
bool result;
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changePeriod();
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applyRedistributionOnAccount(msg.sender);
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baseValue = toBaseAmount(_value);
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result = transferBase(msg.sender, _to, baseValue);
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emit Transfer(msg.sender, _to, _value);
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return result;
}
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// Implements ERC20, triggers tax and/or redistribution
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function transferFrom(address _from, address _to, uint256 _value) public returns (bool) {
uint256 baseValue;
bool result;
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changePeriod();
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applyRedistributionOnAccount(msg.sender);
baseValue = toBaseAmount(_value);
require(allowance[_from][msg.sender] >= baseValue);
result = transferBase(_from, _to, baseValue);
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emit Transfer(_from, _to, _value);
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return result;
}
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// ERC20 transfer backend for transfer, transferFrom
function transferBase(address _from, address _to, uint256 _value) private returns (bool) {
uint256 period;
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decreaseBaseBalance(_from, _value);
increaseBaseBalance(_to, _value);
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period = actualPeriod();
if (_value >= minimumParticipantSpend && accountPeriod(_from) != period && _from != _to) {
registerAccountPeriod(_from, period);
}
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return true;
}
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// Implements EIP173
function transferOwnership(address _newOwner) public returns (bool) {
require(msg.sender == owner);
newOwner = _newOwner;
}
// Implements OwnedAccepter
function acceptOwnership() public returns (bool) {
address oldOwner;
require(msg.sender == newOwner);
oldOwner = owner;
owner = newOwner;
newOwner = address(0);
emit OwnershipTransferred(oldOwner, owner);
}
// Implements EIP165
function supportsInterface(bytes4 _sum) public pure returns (bool) {
if (_sum == 0xc6bb4b70) { // ERC20
return true;
}
if (_sum == 0x449a52f8) { // Minter
return true;
}
if (_sum == 0x01ffc9a7) { // EIP165
return true;
}
if (_sum == 0x9493f8b2) { // EIP173
return true;
}
if (_sum == 0x37a47be4) { // OwnedAccepter
return true;
}
return false;
}
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}