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erc20-demurrage-token-archive/solidity/DemurrageTokenSingleNocap.sol

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pragma solidity >= 0.8.0;
// SPDX-License-Identifier: GPL-3.0-or-later
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contract DemurrageTokenSingleCap {
// Redistribution bit field, with associated shifts and masks
// (Uses sub-byte boundaries)
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bytes32[] public redistributions; // uint51(unused) | uint64(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 shiftRedistributionDemurrage = 104;
//uint256 constant maskRedistributionDemurrage = 0x0000000000ffffffffffffffffffffffffffff00000000000000000000000000; // ((1 << 36) - 1) << 140
// 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
// Account balances
//mapping (address => uint256) account;
// Cached demurrage amount, ppm with 38 digit resolution
uint128 public demurrageAmount;
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// Cached demurrage timestamp; the timestamp for which demurrageAmount was last calculated
uint256 public demurrageTimestamp;
// Implements EIP172
address public owner;
address newOwner;
// Implements ERC20
string public name;
// Implements ERC20
string public symbol;
// Implements ERC20
uint256 public decimals;
// Implements ERC20
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//uint256 public totalSupply;
uint256 supply;
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// Last executed period
uint256 public lastPeriod;
// Last sink redistribution amount
uint256 public totalSink;
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// Value of burnt tokens (burnt tokens do not decay)
uint256 public burned;
// 128 bit resolution of the demurrage divisor
// (this constant x 1000000 is contained within 128 bits)
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uint256 constant nanoDivider = 100000000000000000000000000; // now nanodivider, 6 zeros less
// remaining decimal positions of nanoDivider to reach 38, equals precision in growth and decay
uint256 constant growthResolutionFactor = 1000000000000;
// demurrage decimal width; 38 places
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uint256 public immutable resolutionFactor = nanoDivider * growthResolutionFactor;
// Timestamp of start of periods (time which contract constructor was called)
uint256 public immutable periodStart;
// Duration of a single redistribution period in seconds
uint256 public immutable periodDuration;
// Demurrage in ppm per minute
uint256 public immutable taxLevel;
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// Addresses allowed to mint new tokens
mapping (address => bool) minter;
// Storage for ERC20 approve/transferFrom methods
mapping (address => mapping (address => uint256 ) ) allowance; // holder -> spender -> amount (amount is subject to demurrage)
// Address to send unallocated redistribution tokens
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address public sinkAddress;
// Implements ERC20
event Transfer(address indexed _from, address indexed _to, uint256 _value);
// Implements ERC20
event Approval(address indexed _owner, address indexed _spender, uint256 _value);
// New tokens minted
event Mint(address indexed _minter, address indexed _beneficiary, uint256 _value);
// New demurrage cache milestone calculated
event Decayed(uint256 indexed _period, uint256 indexed _periodCount, uint256 indexed _oldAmount, uint256 _newAmount);
// When a new period threshold has been crossed
event Period(uint256 _period);
// Redistribution applied on a single eligible account
event Redistribution(address indexed _account, uint256 indexed _period, uint256 _value);
// Temporary event used in development, will be removed on prod
event Debug(bytes32 _foo);
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// Emitted when tokens are burned
event Burn(address indexed _burner, uint256 _value);
// EIP173
event OwnershipTransferred(address indexed previousOwner, address indexed newOwner); // EIP173
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constructor(string memory _name, string memory _symbol, uint8 _decimals, uint128 _taxLevelMinute, uint256 _periodMinutes, address _defaultSinkAddress) public {
// ACL setup
owner = msg.sender;
minter[owner] = true;
// ERC20 setup
name = _name;
symbol = _symbol;
decimals = _decimals;
// Demurrage setup
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demurrageTimestamp = block.timestamp;
periodStart = demurrageTimestamp;
periodDuration = _periodMinutes * 60;
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demurrageAmount = uint128(nanoDivider) * 100;
taxLevel = _taxLevelMinute; // Represents 38 decimal places
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bytes32 initialRedistribution = toRedistribution(0, demurrageAmount, 0, 1);
redistributions.push(initialRedistribution);
// Misc settings
sinkAddress = _defaultSinkAddress;
}
// Change sink address for redistribution
function setSinkAddress(address _sinkAddress) public {
require(msg.sender == owner);
sinkAddress = _sinkAddress;
}
// Given address will be allowed to call the mintTo() function
function addMinter(address _minter) public returns (bool) {
require(msg.sender == owner);
minter[_minter] = true;
return true;
}
// 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;
}
// Deserialize the pemurrage period for the given account is participating in
function accountPeriod(address _account) public view returns (uint256) {
return (uint256(account[_account]) & maskAccountPeriod) >> shiftAccountPeriod;
}
// 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);
tmpRedistribution &= (~maskRedistributionParticipants);
tmpRedistribution |= ((participants << shiftRedistributionParticipants) & maskRedistributionParticipants);
redistributions[redistributions.length-1] = bytes32(tmpRedistribution);
return true;
}
// Save the given demurrage period as the currently participation period for the given address
function registerAccountPeriod(address _account, uint256 _period) private returns (bool) {
account[_account] &= bytes32(~maskAccountPeriod);
account[_account] |= bytes32((_period << shiftAccountPeriod) & maskAccountPeriod);
incrementRedistributionParticipants();
return true;
}
/// Implements ERC20
function balanceOf(address _account) public view returns (uint256) {
uint256 baseBalance;
uint256 currentDemurragedAmount;
uint256 periodCount;
baseBalance = baseBalanceOf(_account);
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periodCount = getMinutesDelta(demurrageTimestamp);
currentDemurragedAmount = uint128(decayBy(demurrageAmount * 10000000000, periodCount));
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return (baseBalance * currentDemurragedAmount) / (nanoDivider * 1000000000000);
}
/// Balance unmodified by demurrage
function baseBalanceOf(address _account) public view returns (uint256) {
return uint256(account[_account]) & maskAccountValue;
}
/// Increases base balance for a single account
function increaseBaseBalance(address _account, uint256 _delta) private returns (bool) {
uint256 oldBalance;
uint256 newBalance;
uint256 workAccount;
workAccount = uint256(account[_account]);
if (_delta == 0) {
return false;
}
oldBalance = baseBalanceOf(_account);
newBalance = oldBalance + _delta;
require(uint160(newBalance) > uint160(oldBalance), 'ERR_WOULDWRAP'); // revert if increase would result in a wrapped value
workAccount &= (~maskAccountValue);
workAccount |= (newBalance & maskAccountValue);
account[_account] = bytes32(workAccount);
return true;
}
/// Decreases base balance for a single account
function decreaseBaseBalance(address _account, uint256 _delta) private returns (bool) {
uint256 oldBalance;
uint256 newBalance;
uint256 workAccount;
workAccount = uint256(account[_account]);
if (_delta == 0) {
return false;
}
oldBalance = baseBalanceOf(_account);
require(oldBalance >= _delta, 'ERR_OVERSPEND'); // overspend guard
newBalance = oldBalance - _delta;
workAccount &= (~maskAccountValue);
workAccount |= (newBalance & maskAccountValue);
account[_account] = bytes32(workAccount);
return true;
}
// /// Balance unmodified by demurrage
// function baseBalanceOf(address _account) public view returns (uint256) {
// return account[_account];
// }
//
// /// Increases base balance for a single account
// function increaseBaseBalance(address _account, uint256 _delta) private returns (bool) {
// uint256 oldBalance;
// uint256 newBalance;
// uint256 workAccount;
//
// workAccount = uint256(account[_account]);
//
// if (_delta == 0) {
// return false;
// }
//
// oldBalance = baseBalanceOf(_account);
// account[_account] = oldBalance + _delta;
// return true;
// }
//
// /// Decreases base balance for a single account
// function decreaseBaseBalance(address _account, uint256 _delta) private returns (bool) {
// uint256 oldBalance;
// uint256 newBalance;
// uint256 workAccount;
//
// workAccount = uint256(account[_account]);
//
// if (_delta == 0) {
// return false;
// }
//
// oldBalance = baseBalanceOf(_account);
// require(oldBalance >= _delta, 'ERR_OVERSPEND'); // overspend guard
// account[_account] = oldBalance - _delta;
// return true;
// }
// Creates new tokens out of thin air, and allocates them to the given address
// Triggers tax
function mintTo(address _beneficiary, uint256 _amount) external returns (bool) {
uint256 baseAmount;
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require(minter[msg.sender], 'ERR_ACCESS');
changePeriod();
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baseAmount = toBaseAmount(_amount);
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supply += _amount;
increaseBaseBalance(_beneficiary, baseAmount);
emit Mint(msg.sender, _beneficiary, _amount);
saveRedistributionSupply();
return true;
}
// Deserializes the redistribution word
// uint95(unused) | uint20(demurrageModifier) | uint36(participants) | uint72(value) | uint32(period)
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function toRedistribution(uint256 _participants, uint256 _demurrageModifierPpm, uint256 _value, uint256 _period) public pure returns(bytes32) {
bytes32 redistribution;
redistribution |= bytes32((_demurrageModifierPpm << shiftRedistributionDemurrage) & maskRedistributionDemurrage);
redistribution |= bytes32((_value << shiftRedistributionValue) & maskRedistributionValue);
redistribution |= bytes32(_period & maskRedistributionPeriod);
return redistribution;
}
// Serializes the demurrage period part of the redistribution word
function toRedistributionPeriod(bytes32 redistribution) public pure returns (uint256) {
return uint256(redistribution) & maskRedistributionPeriod;
}
// Serializes the supply part of the redistribution word
function toRedistributionSupply(bytes32 redistribution) public pure returns (uint256) {
return (uint256(redistribution) & maskRedistributionValue) >> shiftRedistributionValue;
}
// Serializes the number of participants part of the redistribution word
function toRedistributionDemurrageModifier(bytes32 redistribution) public pure returns (uint256) {
return (uint256(redistribution) & maskRedistributionDemurrage) >> shiftRedistributionDemurrage;
}
// Serializes the number of participants part of the redistribution word
function toRedistributionParticipants(bytes32 redistribution) public pure returns (uint256) {
return (uint256(redistribution) & maskRedistributionParticipants) >> shiftRedistributionParticipants;
}
// Client accessor to the redistributions array length
function redistributionCount() public view returns (uint256) {
return redistributions.length;
}
// Save the current total supply amount to the current redistribution period
function saveRedistributionSupply() private returns (bool) {
uint256 currentRedistribution;
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uint256 grownSupply;
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grownSupply = totalSupply();
currentRedistribution = uint256(redistributions[redistributions.length-1]);
currentRedistribution &= (~maskRedistributionValue);
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currentRedistribution |= (grownSupply << shiftRedistributionValue);
redistributions[redistributions.length-1] = bytes32(currentRedistribution);
return true;
}
// Get the demurrage period of the current block number
function actualPeriod() public view returns (uint128) {
return uint128((block.timestamp - periodStart) / periodDuration + 1);
}
// Retrieve next redistribution if the period threshold has been crossed
function checkPeriod() private view returns (bytes32) {
bytes32 lastRedistribution;
uint256 currentPeriod;
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lastRedistribution = redistributions[lastPeriod];
currentPeriod = this.actualPeriod();
if (currentPeriod <= toRedistributionPeriod(lastRedistribution)) {
return bytes32(0x00);
}
return lastRedistribution;
}
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function getDistribution(uint256 _supply, uint256 _demurrageAmount) public view returns (uint256) {
uint256 difference;
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difference = _supply * (resolutionFactor - (_demurrageAmount * 10000000000));
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return difference / resolutionFactor;
}
function getDistributionFromRedistribution(bytes32 _redistribution) public returns (uint256) {
uint256 redistributionSupply;
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uint256 redistributionDemurrage;
redistributionSupply = toRedistributionSupply(_redistribution);
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redistributionDemurrage = toRedistributionDemurrageModifier(_redistribution);
return getDistribution(redistributionSupply, redistributionDemurrage);
}
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// Returns the amount sent to the sink address
function applyDefaultRedistribution(bytes32 _redistribution) private returns (uint256) {
uint256 unit;
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uint256 baseUnit;
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unit = getDistributionFromRedistribution(_redistribution);
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baseUnit = toBaseAmount(unit) - totalSink;
increaseBaseBalance(sinkAddress, baseUnit);
lastPeriod += 1;
totalSink += baseUnit;
registerAccountPeriod(sinkAddress, lastPeriod);
return unit;
}
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// Calculate the time delta in whole minutes passed between given timestamp and current timestamp
function getMinutesDelta(uint256 _lastTimestamp) public view returns (uint256) {
return (block.timestamp - _lastTimestamp) / 60;
}
// Calculate and cache the demurrage value corresponding to the (period of the) time of the method call
function applyDemurrage() public returns (bool) {
return applyDemurrageLimited(0);
}
function applyDemurrageLimited(uint256 _rounds) public returns (bool) {
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uint256 periodCount;
uint256 lastDemurrageAmount;
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periodCount = getMinutesDelta(demurrageTimestamp);
if (periodCount == 0) {
return false;
}
lastDemurrageAmount = demurrageAmount;
// safety limit for exponential calculation to ensure that we can always
// execute this code no matter how much time passes.
if (_rounds > 0 && _rounds < periodCount) {
periodCount = _rounds;
}
demurrageAmount = uint128(decayBy(lastDemurrageAmount, periodCount));
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//demurragePeriod = epochPeriodCount;
demurrageTimestamp = demurrageTimestamp + (periodCount * 60);
emit Decayed(demurrageTimestamp, periodCount, lastDemurrageAmount, demurrageAmount);
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;
}
// Recalculate the demurrage modifier for the new period
// Note that the supply for the consecutive period will be taken at the time of code execution, and thus not necessarily at the time when the redistribution period threshold was crossed.
function changePeriod() public returns (bool) {
bytes32 currentRedistribution;
bytes32 nextRedistribution;
uint256 currentPeriod;
uint256 lastDemurrageAmount;
bytes32 lastRedistribution;
uint256 nextRedistributionDemurrage;
uint256 demurrageCounts;
uint256 nextPeriod;
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applyDemurrage();
currentRedistribution = checkPeriod();
if (currentRedistribution == bytes32(0x00)) {
return false;
}
// calculate the decay from previous redistributino
lastRedistribution = redistributions[lastPeriod];
currentPeriod = toRedistributionPeriod(currentRedistribution);
nextPeriod = currentPeriod + 1;
lastDemurrageAmount = toRedistributionDemurrageModifier(lastRedistribution);
demurrageCounts = periodDuration / 60;
nextRedistributionDemurrage = decayBy(lastDemurrageAmount, demurrageCounts);
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nextRedistribution = toRedistribution(0, nextRedistributionDemurrage, totalSupply(), nextPeriod);
redistributions.push(nextRedistribution);
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applyDefaultRedistribution(nextRedistribution);
emit Period(nextPeriod);
return true;
}
// 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;
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valueFactor = growthResolutionFactor;
truncatedTaxLevel = taxLevel / nanoDivider;
for (uint256 i = 0; i < _period; i++) {
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valueFactor = valueFactor + ((valueFactor * truncatedTaxLevel) / growthResolutionFactor);
}
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return (valueFactor * _value) / growthResolutionFactor;
}
// Calculate a value reduced by demurrage by the given period
function decayBy(uint256 _value, uint256 _period) public view returns (uint256) {
uint256 valueFactor;
uint256 truncatedTaxLevel;
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valueFactor = growthResolutionFactor;
truncatedTaxLevel = taxLevel / nanoDivider;
for (uint256 i = 0; i < _period; i++) {
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valueFactor = valueFactor - ((valueFactor * truncatedTaxLevel) / growthResolutionFactor);
}
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return (valueFactor * _value) / growthResolutionFactor;
}
// Inflates the given amount according to the current demurrage modifier
function toBaseAmount(uint256 _value) public view returns (uint256) {
return (_value * resolutionFactor) / (demurrageAmount * 10000000000);
}
// Implements ERC20, triggers tax and/or redistribution
function approve(address _spender, uint256 _value) public returns (bool) {
uint256 baseValue;
if (allowance[msg.sender][_spender] > 0) {
require(_value == 0, 'ZERO_FIRST');
}
changePeriod();
baseValue = toBaseAmount(_value);
allowance[msg.sender][_spender] = baseValue;
emit Approval(msg.sender, _spender, _value);
return true;
}
// Reduce allowance by amount
function decreaseAllowance(address _spender, uint256 _value) public returns (bool) {
uint256 baseValue;
baseValue = toBaseAmount(_value);
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require(allowance[msg.sender][_spender] >= baseValue);
changePeriod();
allowance[msg.sender][_spender] -= baseValue;
emit Approval(msg.sender, _spender, allowance[msg.sender][_spender]);
return true;
}
// Increase allowance by amount
function increaseAllowance(address _spender, uint256 _value) public returns (bool) {
uint256 baseValue;
changePeriod();
baseValue = toBaseAmount(_value);
allowance[msg.sender][_spender] += baseValue;
emit Approval(msg.sender, _spender, allowance[msg.sender][_spender]);
return true;
}
// Implements ERC20, triggers tax and/or redistribution
function transfer(address _to, uint256 _value) public returns (bool) {
uint256 baseValue;
bool result;
changePeriod();
baseValue = toBaseAmount(_value);
result = transferBase(msg.sender, _to, baseValue);
emit Transfer(msg.sender, _to, _value);
return result;
}
// Implements ERC20, triggers tax and/or redistribution
function transferFrom(address _from, address _to, uint256 _value) public returns (bool) {
uint256 baseValue;
bool result;
changePeriod();
baseValue = toBaseAmount(_value);
require(allowance[_from][msg.sender] >= baseValue);
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allowance[_from][msg.sender] -= baseValue;
result = transferBase(_from, _to, baseValue);
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emit Transfer(_from, _to, _value);
return result;
}
// ERC20 transfer backend for transfer, transferFrom
function transferBase(address _from, address _to, uint256 _value) private returns (bool) {
uint256 period;
decreaseBaseBalance(_from, _value);
increaseBaseBalance(_to, _value);
period = actualPeriod();
if (accountPeriod(_from) != period && _from != _to) {
registerAccountPeriod(_from, period);
}
return true;
}
// 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);
}
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// Explicitly and irretrievably burn tokens
// Only token minters can burn tokens
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function burn(uint256 _value) public {
require(minter[msg.sender]);
//require(_value <= account[msg.sender]);
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uint256 _delta = toBaseAmount(_value);
applyDemurrage();
decreaseBaseBalance(msg.sender, _delta);
burned += _value;
emit Burn(msg.sender, _value);
}
// Implements ERC20
function totalSupply() public view returns (uint256) {
return supply - burned;
}
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// Return total number of burned tokens
function totalBurned() public view returns (uint256) {
return burned;
}
// 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;
}
}