Transaction Hash:
Block:
6338844 at Sep-15-2018 11:02:39 PM +UTC
Transaction Fee:
0.00196286625 ETH
$3.69
Gas Used:
290,795 Gas / 6.75 Gwei
Account State Difference:
| Address | Before | After | State Difference | ||
|---|---|---|---|---|---|
|
0xEA674fdD...16B898ec8
Miner
| (Ethermine) | 874.6528219817997115 Eth | 874.6547848480497115 Eth | 0.00196286625 | |
| 0xEC17E28e...A5658AC6F |
37.704337613453849916 Eth
Nonce: 762
|
37.702374747203849916 Eth
Nonce: 763
| 0.00196286625 |
Execution Trace
ETH 2.386250650907610112
BancorConverter.quickConvertPrioritized( _path=[0xc0829421C1d260BD3cB3E0F06cfE2D52db2cE315, 0x1F573D6Fb3F13d689FF844B4cE37794d79a7FF1C, 0x1F573D6Fb3F13d689FF844B4cE37794d79a7FF1C, 0x47244bC49D90F25473eBf8aD0A14Ea6d4232A4c7, 0x6745fAB6801e376cD24F03572B9C9B0D4EdDDCcf], _amount=2386250650907610112, _minReturn=6750194210250, _block=6338902, _v=28, _r=D77D6A61E1BE040BE90B9CFEECB54842523A83E05DB8168026E241D1507D8294, _s=36CAFC02E3B124CF2AB8726FDEA872B6D329979ACD402C24DE4591759B53A92F )
-
ContractRegistry.getAddress( _contractName=42616E636F724E6574776F726B00000000000000000000000000000000000000 ) => ( 0xF20b9e713A33F61fA38792d2aFaF1cD30339126A ) ETH 2.386250650907610112
BancorNetwork.convertForPrioritized2( _path=[0xc0829421C1d260BD3cB3E0F06cfE2D52db2cE315, 0x1F573D6Fb3F13d689FF844B4cE37794d79a7FF1C, 0x1F573D6Fb3F13d689FF844B4cE37794d79a7FF1C, 0x47244bC49D90F25473eBf8aD0A14Ea6d4232A4c7, 0x6745fAB6801e376cD24F03572B9C9B0D4EdDDCcf], _amount=2386250650907610112, _minReturn=6750194210250, _for=0xEC17E28e9E289226134a512169d1aEFA5658AC6F, _block=6338902, _v=28, _r=D77D6A61E1BE040BE90B9CFEECB54842523A83E05DB8168026E241D1507D8294, _s=36CAFC02E3B124CF2AB8726FDEA872B6D329979ACD402C24DE4591759B53A92F )- ETH 2.386250650907610112
EtherToken.CALL( )
-
Null: 0x000...001.0e0ccdad( ) -
ContractRegistry.getAddress( _contractName=436F6E7472616374466561747572657300000000000000000000000000000000 ) => ( 0x563172281800B139f69fB038cC2C08CaD56Ce699 ) -
SmartToken.CALL( )
-
ContractFeatures.isSupported( _contract=0x3839416bd0095d97bE9b354cBfB0F6807d4d609E, _features=1 ) => ( True ) -
BancorConverter.CALL( ) -
EtherToken.allowance( 0xF20b9e713A33F61fA38792d2aFaF1cD30339126A, 0x3839416bd0095d97bE9b354cBfB0F6807d4d609E ) => ( 0 )
-
EtherToken.allowance( 0xF20b9e713A33F61fA38792d2aFaF1cD30339126A, 0x3839416bd0095d97bE9b354cBfB0F6807d4d609E ) => ( 0 )
-
EtherToken.approve( _spender=0x3839416bd0095d97bE9b354cBfB0F6807d4d609E, _value=2386250650907610112 ) => ( success=True )
BancorConverter.change( _fromToken=0xc0829421C1d260BD3cB3E0F06cfE2D52db2cE315, _toToken=0x1F573D6Fb3F13d689FF844B4cE37794d79a7FF1C, _amount=2386250650907610112, _minReturn=1 ) => ( 370853670069042384147 )-
ContractRegistry.getAddress( _contractName=42616E636F724E6574776F726B00000000000000000000000000000000000000 ) => ( 0xF20b9e713A33F61fA38792d2aFaF1cD30339126A ) -
SmartToken.CALL( )
-
SmartToken.CALL( )
-
ContractRegistry.getAddress( _contractName=42616E636F72466F726D756C6100000000000000000000000000000000000000 ) => ( 0xFFd2de852B694F88656e91D9DEfa6b425c454742 ) -
BancorFormula.calculatePurchaseReturn( _supply=78252103773872011175963200, _connectorBalance=50350088564844734585314, _connectorWeight=100000, _depositAmount=2386250650907610112 ) => ( 370853670069042384147 ) -
EtherToken.transferFrom( _from=0xF20b9e713A33F61fA38792d2aFaF1cD30339126A, _to=0x3839416bd0095d97bE9b354cBfB0F6807d4d609E, _value=2386250650907610112 ) => ( success=True )
-
SmartToken.issue( _to=0xF20b9e713A33F61fA38792d2aFaF1cD30339126A, _amount=370853670069042384147 )
-
SmartToken.CALL( )
-
-
SmartToken.CALL( )
-
ContractFeatures.isSupported( _contract=0xC31db08240A11Df6a4c159FF4E6d69f484Fc3828, _features=1 ) => ( True ) -
BancorConverter.CALL( ) -
SmartToken.allowance( 0xF20b9e713A33F61fA38792d2aFaF1cD30339126A, 0xC31db08240A11Df6a4c159FF4E6d69f484Fc3828 ) => ( 0 )
-
SmartToken.allowance( 0xF20b9e713A33F61fA38792d2aFaF1cD30339126A, 0xC31db08240A11Df6a4c159FF4E6d69f484Fc3828 ) => ( 0 )
-
SmartToken.approve( _spender=0xC31db08240A11Df6a4c159FF4E6d69f484Fc3828, _value=370853670069042384147 ) => ( success=True )
BancorConverter.change( _fromToken=0x1F573D6Fb3F13d689FF844B4cE37794d79a7FF1C, _toToken=0x6745fAB6801e376cD24F03572B9C9B0D4EdDDCcf, _amount=370853670069042384147, _minReturn=6750194210250 )-
ContractRegistry.getAddress( _contractName=42616E636F724E6574776F726B00000000000000000000000000000000000000 ) => ( 0xF20b9e713A33F61fA38792d2aFaF1cD30339126A ) -
SmartToken.CALL( )
-
SmartToken.balanceOf( 0xC31db08240A11Df6a4c159FF4E6d69f484Fc3828 ) => ( 40104680115561986543858 )
-
ElementToken.balanceOf( _owner=0xC31db08240A11Df6a4c159FF4E6d69f484Fc3828 ) => ( balance=715489536998073 )
-
ContractRegistry.getAddress( _contractName=42616E636F72466F726D756C6100000000000000000000000000000000000000 ) => ( 0xFFd2de852B694F88656e91D9DEfa6b425c454742 ) -
BancorFormula.calculateCrossConnectorReturn( _fromConnectorBalance=40104680115561986543858, _fromConnectorWeight=500000, _toConnectorBalance=715489536998073, _toConnectorWeight=500000, _amount=370853670069042384147 ) => ( 6555612634957 )
-
- ETH 2.386250650907610112
quickConvertPrioritized[BancorConverter (ln:1071)]
getAddress[BancorConverter (ln:1078)]destroy[BancorConverter (ln:1087)]issue[BancorConverter (ln:1088)]transferFrom[BancorConverter (ln:1091)]value[BancorConverter (ln:1096)]
File 1 of 11: BancorConverter
File 2 of 11: ContractRegistry
File 3 of 11: BancorNetwork
File 4 of 11: EtherToken
File 5 of 11: ContractRegistry
File 6 of 11: SmartToken
File 7 of 11: ContractFeatures
File 8 of 11: BancorFormula
File 9 of 11: SmartToken
File 10 of 11: BancorConverter
File 11 of 11: ElementToken
pragma solidity ^0.4.21;
/*
Owned contract interface
*/
contract IOwned {
// this function isn't abstract since the compiler emits automatically generated getter functions as external
function owner() public view returns (address) {}
function transferOwnership(address _newOwner) public;
function acceptOwnership() public;
}
/*
ERC20 Standard Token interface
*/
contract IERC20Token {
// these functions aren't abstract since the compiler emits automatically generated getter functions as external
function name() public view returns (string) {}
function symbol() public view returns (string) {}
function decimals() public view returns (uint8) {}
function totalSupply() public view returns (uint256) {}
function balanceOf(address _owner) public view returns (uint256) { _owner; }
function allowance(address _owner, address _spender) public view returns (uint256) { _owner; _spender; }
function transfer(address _to, uint256 _value) public returns (bool success);
function transferFrom(address _from, address _to, uint256 _value) public returns (bool success);
function approve(address _spender, uint256 _value) public returns (bool success);
}
/*
Smart Token interface
*/
contract ISmartToken is IOwned, IERC20Token {
function disableTransfers(bool _disable) public;
function issue(address _to, uint256 _amount) public;
function destroy(address _from, uint256 _amount) public;
}
/*
Contract Registry interface
*/
contract IContractRegistry {
function getAddress(bytes32 _contractName) public view returns (address);
}
/*
Contract Features interface
*/
contract IContractFeatures {
function isSupported(address _contract, uint256 _features) public view returns (bool);
function enableFeatures(uint256 _features, bool _enable) public;
}
/*
Whitelist interface
*/
contract IWhitelist {
function isWhitelisted(address _address) public view returns (bool);
}
/*
Token Holder interface
*/
contract ITokenHolder is IOwned {
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount) public;
}
/*
Bancor Formula interface
*/
contract IBancorFormula {
function calculatePurchaseReturn(uint256 _supply, uint256 _connectorBalance, uint32 _connectorWeight, uint256 _depositAmount) public view returns (uint256);
function calculateSaleReturn(uint256 _supply, uint256 _connectorBalance, uint32 _connectorWeight, uint256 _sellAmount) public view returns (uint256);
function calculateCrossConnectorReturn(uint256 _fromConnectorBalance, uint32 _fromConnectorWeight, uint256 _toConnectorBalance, uint32 _toConnectorWeight, uint256 _amount) public view returns (uint256);
}
/*
Bancor Converter interface
*/
contract IBancorConverter {
function getReturn(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount) public view returns (uint256);
function convert(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256);
function conversionWhitelist() public view returns (IWhitelist) {}
// deprecated, backward compatibility
function change(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256);
}
/*
Bancor Network interface
*/
contract IBancorNetwork {
function convert(IERC20Token[] _path, uint256 _amount, uint256 _minReturn) public payable returns (uint256);
function convertFor(IERC20Token[] _path, uint256 _amount, uint256 _minReturn, address _for) public payable returns (uint256);
function convertForPrioritized2(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
address _for,
uint256 _block,
uint8 _v,
bytes32 _r,
bytes32 _s)
public payable returns (uint256);
// deprecated, backward compatibility
function convertForPrioritized(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
address _for,
uint256 _block,
uint256 _nonce,
uint8 _v,
bytes32 _r,
bytes32 _s)
public payable returns (uint256);
}
/*
Utilities & Common Modifiers
*/
contract Utils {
/**
constructor
*/
function Utils() public {
}
// verifies that an amount is greater than zero
modifier greaterThanZero(uint256 _amount) {
require(_amount > 0);
_;
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != address(0));
_;
}
// verifies that the address is different than this contract address
modifier notThis(address _address) {
require(_address != address(this));
_;
}
// Overflow protected math functions
/**
@dev returns the sum of _x and _y, asserts if the calculation overflows
@param _x value 1
@param _y value 2
@return sum
*/
function safeAdd(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x + _y;
assert(z >= _x);
return z;
}
/**
@dev returns the difference of _x minus _y, asserts if the subtraction results in a negative number
@param _x minuend
@param _y subtrahend
@return difference
*/
function safeSub(uint256 _x, uint256 _y) internal pure returns (uint256) {
assert(_x >= _y);
return _x - _y;
}
/**
@dev returns the product of multiplying _x by _y, asserts if the calculation overflows
@param _x factor 1
@param _y factor 2
@return product
*/
function safeMul(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x * _y;
assert(_x == 0 || z / _x == _y);
return z;
}
}
/*
Provides support and utilities for contract ownership
*/
contract Owned is IOwned {
address public owner;
address public newOwner;
event OwnerUpdate(address indexed _prevOwner, address indexed _newOwner);
/**
@dev constructor
*/
function Owned() public {
owner = msg.sender;
}
// allows execution by the owner only
modifier ownerOnly {
assert(msg.sender == owner);
_;
}
/**
@dev allows transferring the contract ownership
the new owner still needs to accept the transfer
can only be called by the contract owner
@param _newOwner new contract owner
*/
function transferOwnership(address _newOwner) public ownerOnly {
require(_newOwner != owner);
newOwner = _newOwner;
}
/**
@dev used by a new owner to accept an ownership transfer
*/
function acceptOwnership() public {
require(msg.sender == newOwner);
emit OwnerUpdate(owner, newOwner);
owner = newOwner;
newOwner = address(0);
}
}
/*
Provides support and utilities for contract management
Note that a managed contract must also have an owner
*/
contract Managed is Owned {
address public manager;
address public newManager;
event ManagerUpdate(address indexed _prevManager, address indexed _newManager);
/**
@dev constructor
*/
function Managed() public {
manager = msg.sender;
}
// allows execution by the manager only
modifier managerOnly {
assert(msg.sender == manager);
_;
}
// allows execution by either the owner or the manager only
modifier ownerOrManagerOnly {
require(msg.sender == owner || msg.sender == manager);
_;
}
/**
@dev allows transferring the contract management
the new manager still needs to accept the transfer
can only be called by the contract manager
@param _newManager new contract manager
*/
function transferManagement(address _newManager) public ownerOrManagerOnly {
require(_newManager != manager);
newManager = _newManager;
}
/**
@dev used by a new manager to accept a management transfer
*/
function acceptManagement() public {
require(msg.sender == newManager);
emit ManagerUpdate(manager, newManager);
manager = newManager;
newManager = address(0);
}
}
/**
Id definitions for bancor contracts
Can be used in conjunction with the contract registry to get contract addresses
*/
contract ContractIds {
// generic
bytes32 public constant CONTRACT_FEATURES = "ContractFeatures";
// bancor logic
bytes32 public constant BANCOR_NETWORK = "BancorNetwork";
bytes32 public constant BANCOR_FORMULA = "BancorFormula";
bytes32 public constant BANCOR_GAS_PRICE_LIMIT = "BancorGasPriceLimit";
bytes32 public constant BANCOR_CONVERTER_FACTORY = "BancorConverterFactory";
bytes32 public constant BANCOR_CONVERTER_UPGRADER = "BancorConverterUpgrader";
// tokens
bytes32 public constant BNT_TOKEN = "BNTToken";
}
/**
Id definitions for bancor contract features
Can be used to query the ContractFeatures contract to check whether a certain feature is supported by a contract
*/
contract FeatureIds {
// converter features
uint256 public constant CONVERTER_CONVERSION_WHITELIST = 1 << 0;
}
/*
We consider every contract to be a 'token holder' since it's currently not possible
for a contract to deny receiving tokens.
The TokenHolder's contract sole purpose is to provide a safety mechanism that allows
the owner to send tokens that were sent to the contract by mistake back to their sender.
*/
contract TokenHolder is ITokenHolder, Owned, Utils {
/**
@dev constructor
*/
function TokenHolder() public {
}
/**
@dev withdraws tokens held by the contract and sends them to an account
can only be called by the owner
@param _token ERC20 token contract address
@param _to account to receive the new amount
@param _amount amount to withdraw
*/
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount)
public
ownerOnly
validAddress(_token)
validAddress(_to)
notThis(_to)
{
assert(_token.transfer(_to, _amount));
}
}
/*
The smart token controller is an upgradable part of the smart token that allows
more functionality as well as fixes for bugs/exploits.
Once it accepts ownership of the token, it becomes the token's sole controller
that can execute any of its functions.
To upgrade the controller, ownership must be transferred to a new controller, along with
any relevant data.
The smart token must be set on construction and cannot be changed afterwards.
Wrappers are provided (as opposed to a single 'execute' function) for each of the token's functions, for easier access.
Note that the controller can transfer token ownership to a new controller that
doesn't allow executing any function on the token, for a trustless solution.
Doing that will also remove the owner's ability to upgrade the controller.
*/
contract SmartTokenController is TokenHolder {
ISmartToken public token; // smart token
/**
@dev constructor
*/
function SmartTokenController(ISmartToken _token)
public
validAddress(_token)
{
token = _token;
}
// ensures that the controller is the token's owner
modifier active() {
assert(token.owner() == address(this));
_;
}
// ensures that the controller is not the token's owner
modifier inactive() {
assert(token.owner() != address(this));
_;
}
/**
@dev allows transferring the token ownership
the new owner still need to accept the transfer
can only be called by the contract owner
@param _newOwner new token owner
*/
function transferTokenOwnership(address _newOwner) public ownerOnly {
token.transferOwnership(_newOwner);
}
/**
@dev used by a new owner to accept a token ownership transfer
can only be called by the contract owner
*/
function acceptTokenOwnership() public ownerOnly {
token.acceptOwnership();
}
/**
@dev disables/enables token transfers
can only be called by the contract owner
@param _disable true to disable transfers, false to enable them
*/
function disableTokenTransfers(bool _disable) public ownerOnly {
token.disableTransfers(_disable);
}
/**
@dev withdraws tokens held by the controller and sends them to an account
can only be called by the owner
@param _token ERC20 token contract address
@param _to account to receive the new amount
@param _amount amount to withdraw
*/
function withdrawFromToken(
IERC20Token _token,
address _to,
uint256 _amount
)
public
ownerOnly
{
ITokenHolder(token).withdrawTokens(_token, _to, _amount);
}
}
/*
Bancor Converter v0.9
The Bancor version of the token converter, allows conversion between a smart token and other ERC20 tokens and between different ERC20 tokens and themselves.
ERC20 connector balance can be virtual, meaning that the calculations are based on the virtual balance instead of relying on
the actual connector balance. This is a security mechanism that prevents the need to keep a very large (and valuable) balance in a single contract.
The converter is upgradable (just like any SmartTokenController).
WARNING: It is NOT RECOMMENDED to use the converter with Smart Tokens that have less than 8 decimal digits
or with very small numbers because of precision loss
Open issues:
- Front-running attacks are currently mitigated by the following mechanisms:
- minimum return argument for each conversion provides a way to define a minimum/maximum price for the transaction
- gas price limit prevents users from having control over the order of execution
- gas price limit check can be skipped if the transaction comes from a trusted, whitelisted signer
Other potential solutions might include a commit/reveal based schemes
- Possibly add getters for the connector fields so that the client won't need to rely on the order in the struct
*/
contract BancorConverter is IBancorConverter, SmartTokenController, Managed, ContractIds, FeatureIds {
uint32 private constant MAX_WEIGHT = 1000000;
uint64 private constant MAX_CONVERSION_FEE = 1000000;
struct Connector {
uint256 virtualBalance; // connector virtual balance
uint32 weight; // connector weight, represented in ppm, 1-1000000
bool isVirtualBalanceEnabled; // true if virtual balance is enabled, false if not
bool isPurchaseEnabled; // is purchase of the smart token enabled with the connector, can be set by the owner
bool isSet; // used to tell if the mapping element is defined
}
string public version = '0.9';
string public converterType = 'bancor';
IContractRegistry public registry; // contract registry contract
IWhitelist public conversionWhitelist; // whitelist contract with list of addresses that are allowed to use the converter
IERC20Token[] public connectorTokens; // ERC20 standard token addresses
IERC20Token[] public quickBuyPath; // conversion path that's used in order to buy the token with ETH
mapping (address => Connector) public connectors; // connector token addresses -> connector data
uint32 private totalConnectorWeight = 0; // used to efficiently prevent increasing the total connector weight above 100%
uint32 public maxConversionFee = 0; // maximum conversion fee for the lifetime of the contract,
// represented in ppm, 0...1000000 (0 = no fee, 100 = 0.01%, 1000000 = 100%)
uint32 public conversionFee = 0; // current conversion fee, represented in ppm, 0...maxConversionFee
bool public conversionsEnabled = true; // true if token conversions is enabled, false if not
IERC20Token[] private convertPath;
// triggered when a conversion between two tokens occurs
event Conversion(
address indexed _fromToken,
address indexed _toToken,
address indexed _trader,
uint256 _amount,
uint256 _return,
int256 _conversionFee
);
// triggered after a conversion with new price data
event PriceDataUpdate(
address indexed _connectorToken,
uint256 _tokenSupply,
uint256 _connectorBalance,
uint32 _connectorWeight
);
// triggered when the conversion fee is updated
event ConversionFeeUpdate(uint32 _prevFee, uint32 _newFee);
/**
@dev constructor
@param _token smart token governed by the converter
@param _registry address of a contract registry contract
@param _maxConversionFee maximum conversion fee, represented in ppm
@param _connectorToken optional, initial connector, allows defining the first connector at deployment time
@param _connectorWeight optional, weight for the initial connector
*/
function BancorConverter(
ISmartToken _token,
IContractRegistry _registry,
uint32 _maxConversionFee,
IERC20Token _connectorToken,
uint32 _connectorWeight
)
public
SmartTokenController(_token)
validAddress(_registry)
validMaxConversionFee(_maxConversionFee)
{
registry = _registry;
IContractFeatures features = IContractFeatures(registry.getAddress(ContractIds.CONTRACT_FEATURES));
// initialize supported features
if (features != address(0))
features.enableFeatures(FeatureIds.CONVERTER_CONVERSION_WHITELIST, true);
maxConversionFee = _maxConversionFee;
if (_connectorToken != address(0))
addConnector(_connectorToken, _connectorWeight, false);
}
// validates a connector token address - verifies that the address belongs to one of the connector tokens
modifier validConnector(IERC20Token _address) {
require(connectors[_address].isSet);
_;
}
// validates a token address - verifies that the address belongs to one of the convertible tokens
modifier validToken(IERC20Token _address) {
require(_address == token || connectors[_address].isSet);
_;
}
// validates maximum conversion fee
modifier validMaxConversionFee(uint32 _conversionFee) {
require(_conversionFee >= 0 && _conversionFee <= MAX_CONVERSION_FEE);
_;
}
// validates conversion fee
modifier validConversionFee(uint32 _conversionFee) {
require(_conversionFee >= 0 && _conversionFee <= maxConversionFee);
_;
}
// validates connector weight range
modifier validConnectorWeight(uint32 _weight) {
require(_weight > 0 && _weight <= MAX_WEIGHT);
_;
}
// validates a conversion path - verifies that the number of elements is odd and that maximum number of 'hops' is 10
modifier validConversionPath(IERC20Token[] _path) {
require(_path.length > 2 && _path.length <= (1 + 2 * 10) && _path.length % 2 == 1);
_;
}
// allows execution only when conversions aren't disabled
modifier conversionsAllowed {
assert(conversionsEnabled);
_;
}
// allows execution by the BancorNetwork contract only
modifier bancorNetworkOnly {
IBancorNetwork bancorNetwork = IBancorNetwork(registry.getAddress(ContractIds.BANCOR_NETWORK));
require(msg.sender == address(bancorNetwork));
_;
}
/**
@dev returns the number of connector tokens defined
@return number of connector tokens
*/
function connectorTokenCount() public view returns (uint16) {
return uint16(connectorTokens.length);
}
/*
@dev allows the owner to update the registry contract address
@param _registry address of a bancor converter registry contract
*/
function setRegistry(IContractRegistry _registry)
public
ownerOnly
validAddress(_registry)
notThis(_registry)
{
registry = _registry;
}
/*
@dev allows the owner to update & enable the conversion whitelist contract address
when set, only addresses that are whitelisted are actually allowed to use the converter
note that the whitelist check is actually done by the BancorNetwork contract
@param _whitelist address of a whitelist contract
*/
function setConversionWhitelist(IWhitelist _whitelist)
public
ownerOnly
notThis(_whitelist)
{
conversionWhitelist = _whitelist;
}
/*
@dev allows the manager to update the quick buy path
@param _path new quick buy path, see conversion path format in the bancorNetwork contract
*/
function setQuickBuyPath(IERC20Token[] _path)
public
ownerOnly
validConversionPath(_path)
{
quickBuyPath = _path;
}
/*
@dev allows the manager to clear the quick buy path
*/
function clearQuickBuyPath() public ownerOnly {
quickBuyPath.length = 0;
}
/**
@dev returns the length of the quick buy path array
@return quick buy path length
*/
function getQuickBuyPathLength() public view returns (uint256) {
return quickBuyPath.length;
}
/**
@dev disables the entire conversion functionality
this is a safety mechanism in case of a emergency
can only be called by the manager
@param _disable true to disable conversions, false to re-enable them
*/
function disableConversions(bool _disable) public ownerOrManagerOnly {
conversionsEnabled = !_disable;
}
/**
@dev updates the current conversion fee
can only be called by the manager
@param _conversionFee new conversion fee, represented in ppm
*/
function setConversionFee(uint32 _conversionFee)
public
ownerOrManagerOnly
validConversionFee(_conversionFee)
{
emit ConversionFeeUpdate(conversionFee, _conversionFee);
conversionFee = _conversionFee;
}
/*
@dev given a return amount, returns the amount minus the conversion fee
@param _amount return amount
@param _magnitude 1 for standard conversion, 2 for cross connector conversion
@return return amount minus conversion fee
*/
function getFinalAmount(uint256 _amount, uint8 _magnitude) public view returns (uint256) {
return safeMul(_amount, (MAX_CONVERSION_FEE - conversionFee) ** _magnitude) / MAX_CONVERSION_FEE ** _magnitude;
}
/**
@dev defines a new connector for the token
can only be called by the owner while the converter is inactive
@param _token address of the connector token
@param _weight constant connector weight, represented in ppm, 1-1000000
@param _enableVirtualBalance true to enable virtual balance for the connector, false to disable it
*/
function addConnector(IERC20Token _token, uint32 _weight, bool _enableVirtualBalance)
public
ownerOnly
inactive
validAddress(_token)
notThis(_token)
validConnectorWeight(_weight)
{
require(_token != token && !connectors[_token].isSet && totalConnectorWeight + _weight <= MAX_WEIGHT); // validate input
connectors[_token].virtualBalance = 0;
connectors[_token].weight = _weight;
connectors[_token].isVirtualBalanceEnabled = _enableVirtualBalance;
connectors[_token].isPurchaseEnabled = true;
connectors[_token].isSet = true;
connectorTokens.push(_token);
totalConnectorWeight += _weight;
}
/**
@dev updates one of the token connectors
can only be called by the owner
@param _connectorToken address of the connector token
@param _weight constant connector weight, represented in ppm, 1-1000000
@param _enableVirtualBalance true to enable virtual balance for the connector, false to disable it
@param _virtualBalance new connector's virtual balance
*/
function updateConnector(IERC20Token _connectorToken, uint32 _weight, bool _enableVirtualBalance, uint256 _virtualBalance)
public
ownerOnly
validConnector(_connectorToken)
validConnectorWeight(_weight)
{
Connector storage connector = connectors[_connectorToken];
require(totalConnectorWeight - connector.weight + _weight <= MAX_WEIGHT); // validate input
totalConnectorWeight = totalConnectorWeight - connector.weight + _weight;
connector.weight = _weight;
connector.isVirtualBalanceEnabled = _enableVirtualBalance;
connector.virtualBalance = _virtualBalance;
}
/**
@dev disables purchasing with the given connector token in case the connector token got compromised
can only be called by the owner
note that selling is still enabled regardless of this flag and it cannot be disabled by the owner
@param _connectorToken connector token contract address
@param _disable true to disable the token, false to re-enable it
*/
function disableConnectorPurchases(IERC20Token _connectorToken, bool _disable)
public
ownerOnly
validConnector(_connectorToken)
{
connectors[_connectorToken].isPurchaseEnabled = !_disable;
}
/**
@dev returns the connector's virtual balance if one is defined, otherwise returns the actual balance
@param _connectorToken connector token contract address
@return connector balance
*/
function getConnectorBalance(IERC20Token _connectorToken)
public
view
validConnector(_connectorToken)
returns (uint256)
{
Connector storage connector = connectors[_connectorToken];
return connector.isVirtualBalanceEnabled ? connector.virtualBalance : _connectorToken.balanceOf(this);
}
/**
@dev returns the expected return for converting a specific amount of _fromToken to _toToken
@param _fromToken ERC20 token to convert from
@param _toToken ERC20 token to convert to
@param _amount amount to convert, in fromToken
@return expected conversion return amount
*/
function getReturn(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount) public view returns (uint256) {
require(_fromToken != _toToken); // validate input
// conversion between the token and one of its connectors
if (_toToken == token)
return getPurchaseReturn(_fromToken, _amount);
else if (_fromToken == token)
return getSaleReturn(_toToken, _amount);
// conversion between 2 connectors
return getCrossConnectorReturn(_fromToken, _toToken, _amount);
}
/**
@dev returns the expected return for buying the token for a connector token
@param _connectorToken connector token contract address
@param _depositAmount amount to deposit (in the connector token)
@return expected purchase return amount
*/
function getPurchaseReturn(IERC20Token _connectorToken, uint256 _depositAmount)
public
view
active
validConnector(_connectorToken)
returns (uint256)
{
Connector storage connector = connectors[_connectorToken];
require(connector.isPurchaseEnabled); // validate input
uint256 tokenSupply = token.totalSupply();
uint256 connectorBalance = getConnectorBalance(_connectorToken);
IBancorFormula formula = IBancorFormula(registry.getAddress(ContractIds.BANCOR_FORMULA));
uint256 amount = formula.calculatePurchaseReturn(tokenSupply, connectorBalance, connector.weight, _depositAmount);
// return the amount minus the conversion fee
return getFinalAmount(amount, 1);
}
/**
@dev returns the expected return for selling the token for one of its connector tokens
@param _connectorToken connector token contract address
@param _sellAmount amount to sell (in the smart token)
@return expected sale return amount
*/
function getSaleReturn(IERC20Token _connectorToken, uint256 _sellAmount)
public
view
active
validConnector(_connectorToken)
returns (uint256)
{
Connector storage connector = connectors[_connectorToken];
uint256 tokenSupply = token.totalSupply();
uint256 connectorBalance = getConnectorBalance(_connectorToken);
IBancorFormula formula = IBancorFormula(registry.getAddress(ContractIds.BANCOR_FORMULA));
uint256 amount = formula.calculateSaleReturn(tokenSupply, connectorBalance, connector.weight, _sellAmount);
// return the amount minus the conversion fee
return getFinalAmount(amount, 1);
}
/**
@dev returns the expected return for selling one of the connector tokens for another connector token
@param _fromConnectorToken contract address of the connector token to convert from
@param _toConnectorToken contract address of the connector token to convert to
@param _sellAmount amount to sell (in the from connector token)
@return expected sale return amount (in the to connector token)
*/
function getCrossConnectorReturn(IERC20Token _fromConnectorToken, IERC20Token _toConnectorToken, uint256 _sellAmount)
public
view
active
validConnector(_fromConnectorToken)
validConnector(_toConnectorToken)
returns (uint256)
{
Connector storage fromConnector = connectors[_fromConnectorToken];
Connector storage toConnector = connectors[_toConnectorToken];
require(toConnector.isPurchaseEnabled); // validate input
uint256 fromConnectorBalance = getConnectorBalance(_fromConnectorToken);
uint256 toConnectorBalance = getConnectorBalance(_toConnectorToken);
IBancorFormula formula = IBancorFormula(registry.getAddress(ContractIds.BANCOR_FORMULA));
uint256 amount = formula.calculateCrossConnectorReturn(fromConnectorBalance, fromConnector.weight, toConnectorBalance, toConnector.weight, _sellAmount);
// return the amount minus the conversion fee
// the fee is higher (magnitude = 2) since cross connector conversion equals 2 conversions (from / to the smart token)
return getFinalAmount(amount, 2);
}
/**
@dev converts a specific amount of _fromToken to _toToken
@param _fromToken ERC20 token to convert from
@param _toToken ERC20 token to convert to
@param _amount amount to convert, in fromToken
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return conversion return amount
*/
function convertInternal(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn)
public
bancorNetworkOnly
conversionsAllowed
greaterThanZero(_minReturn)
returns (uint256)
{
require(_fromToken != _toToken); // validate input
// conversion between the token and one of its connectors
if (_toToken == token)
return buy(_fromToken, _amount, _minReturn);
else if (_fromToken == token)
return sell(_toToken, _amount, _minReturn);
// conversion between 2 connectors
uint256 amount = getCrossConnectorReturn(_fromToken, _toToken, _amount);
// ensure the trade gives something in return and meets the minimum requested amount
require(amount != 0 && amount >= _minReturn);
// update the source token virtual balance if relevant
Connector storage fromConnector = connectors[_fromToken];
if (fromConnector.isVirtualBalanceEnabled)
fromConnector.virtualBalance = safeAdd(fromConnector.virtualBalance, _amount);
// update the target token virtual balance if relevant
Connector storage toConnector = connectors[_toToken];
if (toConnector.isVirtualBalanceEnabled)
toConnector.virtualBalance = safeSub(toConnector.virtualBalance, amount);
// ensure that the trade won't deplete the connector balance
uint256 toConnectorBalance = getConnectorBalance(_toToken);
assert(amount < toConnectorBalance);
// transfer funds from the caller in the from connector token
assert(_fromToken.transferFrom(msg.sender, this, _amount));
// transfer funds to the caller in the to connector token
// the transfer might fail if the actual connector balance is smaller than the virtual balance
assert(_toToken.transfer(msg.sender, amount));
// calculate conversion fee and dispatch the conversion event
// the fee is higher (magnitude = 2) since cross connector conversion equals 2 conversions (from / to the smart token)
uint256 feeAmount = safeSub(amount, getFinalAmount(amount, 2));
dispatchConversionEvent(_fromToken, _toToken, _amount, amount, feeAmount);
// dispatch price data updates for the smart token / both connectors
emit PriceDataUpdate(_fromToken, token.totalSupply(), getConnectorBalance(_fromToken), fromConnector.weight);
emit PriceDataUpdate(_toToken, token.totalSupply(), getConnectorBalance(_toToken), toConnector.weight);
return amount;
}
/**
@dev converts a specific amount of _fromToken to _toToken
@param _fromToken ERC20 token to convert from
@param _toToken ERC20 token to convert to
@param _amount amount to convert, in fromToken
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return conversion return amount
*/
function convert(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256) {
convertPath = [_fromToken, token, _toToken];
return quickConvert(convertPath, _amount, _minReturn);
}
/**
@dev buys the token by depositing one of its connector tokens
@param _connectorToken connector token contract address
@param _depositAmount amount to deposit (in the connector token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return buy return amount
*/
function buy(IERC20Token _connectorToken, uint256 _depositAmount, uint256 _minReturn) internal returns (uint256) {
uint256 amount = getPurchaseReturn(_connectorToken, _depositAmount);
// ensure the trade gives something in return and meets the minimum requested amount
require(amount != 0 && amount >= _minReturn);
// update virtual balance if relevant
Connector storage connector = connectors[_connectorToken];
if (connector.isVirtualBalanceEnabled)
connector.virtualBalance = safeAdd(connector.virtualBalance, _depositAmount);
// transfer funds from the caller in the connector token
assert(_connectorToken.transferFrom(msg.sender, this, _depositAmount));
// issue new funds to the caller in the smart token
token.issue(msg.sender, amount);
// calculate conversion fee and dispatch the conversion event
uint256 feeAmount = safeSub(amount, getFinalAmount(amount, 1));
dispatchConversionEvent(_connectorToken, token, _depositAmount, amount, feeAmount);
// dispatch price data update for the smart token/connector
emit PriceDataUpdate(_connectorToken, token.totalSupply(), getConnectorBalance(_connectorToken), connector.weight);
return amount;
}
/**
@dev sells the token by withdrawing from one of its connector tokens
@param _connectorToken connector token contract address
@param _sellAmount amount to sell (in the smart token)
@param _minReturn if the conversion results in an amount smaller the minimum return - it is cancelled, must be nonzero
@return sell return amount
*/
function sell(IERC20Token _connectorToken, uint256 _sellAmount, uint256 _minReturn) internal returns (uint256) {
require(_sellAmount <= token.balanceOf(msg.sender)); // validate input
uint256 amount = getSaleReturn(_connectorToken, _sellAmount);
// ensure the trade gives something in return and meets the minimum requested amount
require(amount != 0 && amount >= _minReturn);
// ensure that the trade will only deplete the connector balance if the total supply is depleted as well
uint256 tokenSupply = token.totalSupply();
uint256 connectorBalance = getConnectorBalance(_connectorToken);
assert(amount < connectorBalance || (amount == connectorBalance && _sellAmount == tokenSupply));
// update virtual balance if relevant
Connector storage connector = connectors[_connectorToken];
if (connector.isVirtualBalanceEnabled)
connector.virtualBalance = safeSub(connector.virtualBalance, amount);
// destroy _sellAmount from the caller's balance in the smart token
token.destroy(msg.sender, _sellAmount);
// transfer funds to the caller in the connector token
// the transfer might fail if the actual connector balance is smaller than the virtual balance
assert(_connectorToken.transfer(msg.sender, amount));
// calculate conversion fee and dispatch the conversion event
uint256 feeAmount = safeSub(amount, getFinalAmount(amount, 1));
dispatchConversionEvent(token, _connectorToken, _sellAmount, amount, feeAmount);
// dispatch price data update for the smart token/connector
emit PriceDataUpdate(_connectorToken, token.totalSupply(), getConnectorBalance(_connectorToken), connector.weight);
return amount;
}
/**
@dev converts the token to any other token in the bancor network by following a predefined conversion path
note that when converting from an ERC20 token (as opposed to a smart token), allowance must be set beforehand
@param _path conversion path, see conversion path format in the BancorNetwork contract
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return tokens issued in return
*/
function quickConvert(IERC20Token[] _path, uint256 _amount, uint256 _minReturn)
public
payable
validConversionPath(_path)
returns (uint256)
{
return quickConvertPrioritized(_path, _amount, _minReturn, 0x0, 0x0, 0x0, 0x0);
}
/**
@dev converts the token to any other token in the bancor network by following a predefined conversion path
note that when converting from an ERC20 token (as opposed to a smart token), allowance must be set beforehand
@param _path conversion path, see conversion path format in the BancorNetwork contract
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@param _block if the current block exceeded the given parameter - it is cancelled
@param _v (signature[128:130]) associated with the signer address and helps validating if the signature is legit
@param _r (signature[0:64]) associated with the signer address and helps validating if the signature is legit
@param _s (signature[64:128]) associated with the signer address and helps validating if the signature is legit
@return tokens issued in return
*/
function quickConvertPrioritized(IERC20Token[] _path, uint256 _amount, uint256 _minReturn, uint256 _block, uint8 _v, bytes32 _r, bytes32 _s)
public
payable
validConversionPath(_path)
returns (uint256)
{
IERC20Token fromToken = _path[0];
IBancorNetwork bancorNetwork = IBancorNetwork(registry.getAddress(ContractIds.BANCOR_NETWORK));
// we need to transfer the source tokens from the caller to the BancorNetwork contract,
// so it can execute the conversion on behalf of the caller
if (msg.value == 0) {
// not ETH, send the source tokens to the BancorNetwork contract
// if the token is the smart token, no allowance is required - destroy the tokens
// from the caller and issue them to the BancorNetwork contract
if (fromToken == token) {
token.destroy(msg.sender, _amount); // destroy _amount tokens from the caller's balance in the smart token
token.issue(bancorNetwork, _amount); // issue _amount new tokens to the BancorNetwork contract
} else {
// otherwise, we assume we already have allowance, transfer the tokens directly to the BancorNetwork contract
assert(fromToken.transferFrom(msg.sender, bancorNetwork, _amount));
}
}
// execute the conversion and pass on the ETH with the call
return bancorNetwork.convertForPrioritized2.value(msg.value)(_path, _amount, _minReturn, msg.sender, _block, _v, _r, _s);
}
// deprecated, backward compatibility
function change(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256) {
return convertInternal(_fromToken, _toToken, _amount, _minReturn);
}
/**
@dev helper, dispatches the Conversion event
@param _fromToken ERC20 token to convert from
@param _toToken ERC20 token to convert to
@param _amount amount purchased/sold (in the source token)
@param _returnAmount amount returned (in the target token)
*/
function dispatchConversionEvent(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _returnAmount, uint256 _feeAmount) private {
// fee amount is converted to 255 bits -
// negative amount means the fee is taken from the source token, positive amount means its taken from the target token
// currently the fee is always taken from the target token
// since we convert it to a signed number, we first ensure that it's capped at 255 bits to prevent overflow
assert(_feeAmount <= 2 ** 255);
emit Conversion(_fromToken, _toToken, msg.sender, _amount, _returnAmount, int256(_feeAmount));
}
/**
@dev fallback, buys the smart token with ETH
note that the purchase will use the price at the time of the purchase
*/
function() payable public {
quickConvert(quickBuyPath, msg.value, 1);
}
}File 2 of 11: ContractRegistry
pragma solidity ^0.4.21;
/*
Owned contract interface
*/
contract IOwned {
// this function isn't abstract since the compiler emits automatically generated getter functions as external
function owner() public view returns (address) {}
function transferOwnership(address _newOwner) public;
function acceptOwnership() public;
}
/*
Provides support and utilities for contract ownership
*/
contract Owned is IOwned {
address public owner;
address public newOwner;
event OwnerUpdate(address indexed _prevOwner, address indexed _newOwner);
/**
@dev constructor
*/
function Owned() public {
owner = msg.sender;
}
// allows execution by the owner only
modifier ownerOnly {
assert(msg.sender == owner);
_;
}
/**
@dev allows transferring the contract ownership
the new owner still needs to accept the transfer
can only be called by the contract owner
@param _newOwner new contract owner
*/
function transferOwnership(address _newOwner) public ownerOnly {
require(_newOwner != owner);
newOwner = _newOwner;
}
/**
@dev used by a new owner to accept an ownership transfer
*/
function acceptOwnership() public {
require(msg.sender == newOwner);
emit OwnerUpdate(owner, newOwner);
owner = newOwner;
newOwner = address(0);
}
}
/*
Contract Registry interface
*/
contract IContractRegistry {
function getAddress(bytes32 _contractName) public view returns (address);
}
/**
Contract Registry
The contract registry keeps contract addresses by name.
The owner can update contract addresses so that a contract name always points to the latest version
of the given contract.
Other contracts can query the registry to get updated addresses instead of depending on specific
addresses.
Note that contract names are limited to 32 bytes, UTF8 strings to optimize gas costs
*/
contract ContractRegistry is IContractRegistry, Owned {
mapping (bytes32 => address) addresses;
event AddressUpdate(bytes32 indexed _contractName, address _contractAddress);
/**
@dev constructor
*/
function ContractRegistry() public {
}
/**
@dev returns the address associated with the given contract name
@param _contractName contract name
@return contract address
*/
function getAddress(bytes32 _contractName) public view returns (address) {
return addresses[_contractName];
}
/**
@dev registers a new address for the contract name
@param _contractName contract name
@param _contractAddress contract address
*/
function registerAddress(bytes32 _contractName, address _contractAddress) public ownerOnly {
require(_contractName.length > 0); // validating input
addresses[_contractName] = _contractAddress;
emit AddressUpdate(_contractName, _contractAddress);
}
}File 3 of 11: BancorNetwork
pragma solidity ^0.4.21;
/*
Owned contract interface
*/
contract IOwned {
// this function isn't abstract since the compiler emits automatically generated getter functions as external
function owner() public view returns (address) {}
function transferOwnership(address _newOwner) public;
function acceptOwnership() public;
}
/*
ERC20 Standard Token interface
*/
contract IERC20Token {
// these functions aren't abstract since the compiler emits automatically generated getter functions as external
function name() public view returns (string) {}
function symbol() public view returns (string) {}
function decimals() public view returns (uint8) {}
function totalSupply() public view returns (uint256) {}
function balanceOf(address _owner) public view returns (uint256) { _owner; }
function allowance(address _owner, address _spender) public view returns (uint256) { _owner; _spender; }
function transfer(address _to, uint256 _value) public returns (bool success);
function transferFrom(address _from, address _to, uint256 _value) public returns (bool success);
function approve(address _spender, uint256 _value) public returns (bool success);
}
/*
Contract Registry interface
*/
contract IContractRegistry {
function getAddress(bytes32 _contractName) public view returns (address);
}
/*
Contract Features interface
*/
contract IContractFeatures {
function isSupported(address _contract, uint256 _features) public view returns (bool);
function enableFeatures(uint256 _features, bool _enable) public;
}
/*
Whitelist interface
*/
contract IWhitelist {
function isWhitelisted(address _address) public view returns (bool);
}
/*
Token Holder interface
*/
contract ITokenHolder is IOwned {
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount) public;
}
/*
Ether Token interface
*/
contract IEtherToken is ITokenHolder, IERC20Token {
function deposit() public payable;
function withdraw(uint256 _amount) public;
function withdrawTo(address _to, uint256 _amount) public;
}
/*
Smart Token interface
*/
contract ISmartToken is IOwned, IERC20Token {
function disableTransfers(bool _disable) public;
function issue(address _to, uint256 _amount) public;
function destroy(address _from, uint256 _amount) public;
}
/*
Bancor Gas Price Limit interface
*/
contract IBancorGasPriceLimit {
function gasPrice() public view returns (uint256) {}
function validateGasPrice(uint256) public view;
}
/*
Bancor Converter interface
*/
contract IBancorConverter {
function getReturn(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount) public view returns (uint256);
function convert(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256);
function conversionWhitelist() public view returns (IWhitelist) {}
// deprecated, backward compatibility
function change(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256);
}
/*
Bancor Network interface
*/
contract IBancorNetwork {
function convert(IERC20Token[] _path, uint256 _amount, uint256 _minReturn) public payable returns (uint256);
function convertFor(IERC20Token[] _path, uint256 _amount, uint256 _minReturn, address _for) public payable returns (uint256);
function convertForPrioritized2(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
address _for,
uint256 _block,
uint8 _v,
bytes32 _r,
bytes32 _s)
public payable returns (uint256);
// deprecated, backward compatibility
function convertForPrioritized(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
address _for,
uint256 _block,
uint256 _nonce,
uint8 _v,
bytes32 _r,
bytes32 _s)
public payable returns (uint256);
}
/*
Utilities & Common Modifiers
*/
contract Utils {
/**
constructor
*/
function Utils() public {
}
// verifies that an amount is greater than zero
modifier greaterThanZero(uint256 _amount) {
require(_amount > 0);
_;
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != address(0));
_;
}
// verifies that the address is different than this contract address
modifier notThis(address _address) {
require(_address != address(this));
_;
}
// Overflow protected math functions
/**
@dev returns the sum of _x and _y, asserts if the calculation overflows
@param _x value 1
@param _y value 2
@return sum
*/
function safeAdd(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x + _y;
assert(z >= _x);
return z;
}
/**
@dev returns the difference of _x minus _y, asserts if the subtraction results in a negative number
@param _x minuend
@param _y subtrahend
@return difference
*/
function safeSub(uint256 _x, uint256 _y) internal pure returns (uint256) {
assert(_x >= _y);
return _x - _y;
}
/**
@dev returns the product of multiplying _x by _y, asserts if the calculation overflows
@param _x factor 1
@param _y factor 2
@return product
*/
function safeMul(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x * _y;
assert(_x == 0 || z / _x == _y);
return z;
}
}
/*
Provides support and utilities for contract ownership
*/
contract Owned is IOwned {
address public owner;
address public newOwner;
event OwnerUpdate(address indexed _prevOwner, address indexed _newOwner);
/**
@dev constructor
*/
function Owned() public {
owner = msg.sender;
}
// allows execution by the owner only
modifier ownerOnly {
assert(msg.sender == owner);
_;
}
/**
@dev allows transferring the contract ownership
the new owner still needs to accept the transfer
can only be called by the contract owner
@param _newOwner new contract owner
*/
function transferOwnership(address _newOwner) public ownerOnly {
require(_newOwner != owner);
newOwner = _newOwner;
}
/**
@dev used by a new owner to accept an ownership transfer
*/
function acceptOwnership() public {
require(msg.sender == newOwner);
emit OwnerUpdate(owner, newOwner);
owner = newOwner;
newOwner = address(0);
}
}
/**
Id definitions for bancor contracts
Can be used in conjunction with the contract registry to get contract addresses
*/
contract ContractIds {
bytes32 public constant BANCOR_NETWORK = "BancorNetwork";
bytes32 public constant BANCOR_FORMULA = "BancorFormula";
bytes32 public constant CONTRACT_FEATURES = "ContractFeatures";
}
/**
Id definitions for bancor contract features
Can be used to query the ContractFeatures contract to check whether a certain feature is supported by a contract
*/
contract FeatureIds {
// converter features
uint256 public constant CONVERTER_CONVERSION_WHITELIST = 1 << 0;
}
/*
We consider every contract to be a 'token holder' since it's currently not possible
for a contract to deny receiving tokens.
The TokenHolder's contract sole purpose is to provide a safety mechanism that allows
the owner to send tokens that were sent to the contract by mistake back to their sender.
*/
contract TokenHolder is ITokenHolder, Owned, Utils {
/**
@dev constructor
*/
function TokenHolder() public {
}
/**
@dev withdraws tokens held by the contract and sends them to an account
can only be called by the owner
@param _token ERC20 token contract address
@param _to account to receive the new amount
@param _amount amount to withdraw
*/
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount)
public
ownerOnly
validAddress(_token)
validAddress(_to)
notThis(_to)
{
assert(_token.transfer(_to, _amount));
}
}
/*
The BancorNetwork contract is the main entry point for bancor token conversions.
It also allows converting between any token in the bancor network to any other token
in a single transaction by providing a conversion path.
A note on conversion path -
Conversion path is a data structure that's used when converting a token to another token in the bancor network
when the conversion cannot necessarily be done by single converter and might require multiple 'hops'.
The path defines which converters should be used and what kind of conversion should be done in each step.
The path format doesn't include complex structure and instead, it is represented by a single array
in which each 'hop' is represented by a 2-tuple - smart token & to token.
In addition, the first element is always the source token.
The smart token is only used as a pointer to a converter (since converter addresses are more likely to change).
Format:
[source token, smart token, to token, smart token, to token...]
*/
contract BancorNetwork is IBancorNetwork, TokenHolder, ContractIds, FeatureIds {
address public signerAddress = 0x0; // verified address that allows conversions with higher gas price
IContractRegistry public registry; // contract registry contract address
IBancorGasPriceLimit public gasPriceLimit; // bancor universal gas price limit contract
mapping (address => bool) public etherTokens; // list of all supported ether tokens
mapping (bytes32 => bool) public conversionHashes; // list of conversion hashes, to prevent re-use of the same hash
/**
@dev constructor
@param _registry address of a contract registry contract
*/
function BancorNetwork(IContractRegistry _registry) public validAddress(_registry) {
registry = _registry;
}
// validates a conversion path - verifies that the number of elements is odd and that maximum number of 'hops' is 10
modifier validConversionPath(IERC20Token[] _path) {
require(_path.length > 2 && _path.length <= (1 + 2 * 10) && _path.length % 2 == 1);
_;
}
/*
@dev allows the owner to update the contract registry contract address
@param _registry address of a contract registry contract
*/
function setContractRegistry(IContractRegistry _registry)
public
ownerOnly
validAddress(_registry)
notThis(_registry)
{
registry = _registry;
}
/*
@dev allows the owner to update the gas price limit contract address
@param _gasPriceLimit address of a bancor gas price limit contract
*/
function setGasPriceLimit(IBancorGasPriceLimit _gasPriceLimit)
public
ownerOnly
validAddress(_gasPriceLimit)
notThis(_gasPriceLimit)
{
gasPriceLimit = _gasPriceLimit;
}
/*
@dev allows the owner to update the signer address
@param _signerAddress new signer address
*/
function setSignerAddress(address _signerAddress)
public
ownerOnly
validAddress(_signerAddress)
notThis(_signerAddress)
{
signerAddress = _signerAddress;
}
/**
@dev allows the owner to register/unregister ether tokens
@param _token ether token contract address
@param _register true to register, false to unregister
*/
function registerEtherToken(IEtherToken _token, bool _register)
public
ownerOnly
validAddress(_token)
notThis(_token)
{
etherTokens[_token] = _register;
}
/**
@dev verifies that the signer address is trusted by recovering
the address associated with the public key from elliptic
curve signature, returns zero on error.
notice that the signature is valid only for one conversion
and expires after the give block.
@return true if the signer is verified
*/
function verifyTrustedSender(IERC20Token[] _path, uint256 _amount, uint256 _block, address _addr, uint8 _v, bytes32 _r, bytes32 _s) private returns(bool) {
bytes32 hash = keccak256(_block, tx.gasprice, _addr, msg.sender, _amount, _path);
// checking that it is the first conversion with the given signature
// and that the current block number doesn't exceeded the maximum block
// number that's allowed with the current signature
require(!conversionHashes[hash] && block.number <= _block);
// recovering the signing address and comparing it to the trusted signer
// address that was set in the contract
bytes32 prefixedHash = keccak256("\x19Ethereum Signed Message:\n32", hash);
bool verified = ecrecover(prefixedHash, _v, _r, _s) == signerAddress;
// if the signer is the trusted signer - mark the hash so that it can't
// be used multiple times
if (verified)
conversionHashes[hash] = true;
return verified;
}
/**
@dev converts the token to any other token in the bancor network by following
a predefined conversion path and transfers the result tokens to a target account
note that the converter should already own the source tokens
@param _path conversion path, see conversion path format above
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@param _for account that will receive the conversion result
@return tokens issued in return
*/
function convertFor(IERC20Token[] _path, uint256 _amount, uint256 _minReturn, address _for) public payable returns (uint256) {
return convertForPrioritized2(_path, _amount, _minReturn, _for, 0x0, 0x0, 0x0, 0x0);
}
/**
@dev converts the token to any other token in the bancor network
by following a predefined conversion path and transfers the result
tokens to a target account.
this version of the function also allows the verified signer
to bypass the universal gas price limit.
note that the converter should already own the source tokens
@param _path conversion path, see conversion path format above
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@param _for account that will receive the conversion result
@return tokens issued in return
*/
function convertForPrioritized2(IERC20Token[] _path, uint256 _amount, uint256 _minReturn, address _for, uint256 _block, uint8 _v, bytes32 _r, bytes32 _s)
public
payable
validConversionPath(_path)
returns (uint256)
{
// if ETH is provided, ensure that the amount is identical to _amount and verify that the source token is an ether token
IERC20Token fromToken = _path[0];
require(msg.value == 0 || (_amount == msg.value && etherTokens[fromToken]));
// if ETH was sent with the call, the source is an ether token - deposit the ETH in it
// otherwise, we assume we already have the tokens
if (msg.value > 0)
IEtherToken(fromToken).deposit.value(msg.value)();
return convertForInternal(_path, _amount, _minReturn, _for, _block, _v, _r, _s);
}
/**
@dev converts token to any other token in the bancor network
by following the predefined conversion paths and transfers the result
tokens to a targeted account.
this version of the function also allows multiple conversions
in a single atomic transaction.
note that the converter should already own the source tokens
@param _paths merged conversion paths, i.e. [path1, path2, ...]. see conversion path format above
@param _pathStartIndex each item in the array is the start index of the nth path in _paths
@param _amounts amount to convert from (in the initial source token) for each path
@param _minReturns minimum return for each path. if the conversion results in an amount
smaller than the minimum return - it is cancelled, must be nonzero
@param _for account that will receive the conversions result
@return amount of conversion result for each path
*/
function convertForMultiple(IERC20Token[] _paths, uint256[] _pathStartIndex, uint256[] _amounts, uint256[] _minReturns, address _for)
public
payable
returns (uint256[])
{
// if ETH is provided, ensure that the total amount was converted into other tokens
uint256 convertedValue = 0;
uint256 pathEndIndex;
// iterate over the conversion paths
for (uint256 i = 0; i < _pathStartIndex.length; i += 1) {
pathEndIndex = i == (_pathStartIndex.length - 1) ? _paths.length : _pathStartIndex[i + 1];
// copy a single path from _paths into an array
IERC20Token[] memory path = new IERC20Token[](pathEndIndex - _pathStartIndex[i]);
for (uint256 j = _pathStartIndex[i]; j < pathEndIndex; j += 1) {
path[j - _pathStartIndex[i]] = _paths[j];
}
// if ETH is provided, ensure that the amount is lower than the path amount and
// verify that the source token is an ether token. otherwise ensure that
// the source is not an ether token
IERC20Token fromToken = path[0];
require(msg.value == 0 || (_amounts[i] <= msg.value && etherTokens[fromToken]) || !etherTokens[fromToken]);
// if ETH was sent with the call, the source is an ether token - deposit the ETH path amount in it.
// otherwise, we assume we already have the tokens
if (msg.value > 0 && etherTokens[fromToken]) {
IEtherToken(fromToken).deposit.value(_amounts[i])();
convertedValue += _amounts[i];
}
_amounts[i] = convertForInternal(path, _amounts[i], _minReturns[i], _for, 0x0, 0x0, 0x0, 0x0);
}
// if ETH was provided, ensure that the full amount was converted
require(convertedValue == msg.value);
return _amounts;
}
/**
@dev converts token to any other token in the bancor network
by following a predefined conversion paths and transfers the result
tokens to a target account.
@param _path conversion path, see conversion path format above
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@param _for account that will receive the conversion result
@param _block if the current block exceeded the given parameter - it is cancelled
@param _v (signature[128:130]) associated with the signer address and helps to validate if the signature is legit
@param _r (signature[0:64]) associated with the signer address and helps to validate if the signature is legit
@param _s (signature[64:128]) associated with the signer address and helps to validate if the signature is legit
@return tokens issued in return
*/
function convertForInternal(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
address _for,
uint256 _block,
uint8 _v,
bytes32 _r,
bytes32 _s
)
private
validConversionPath(_path)
returns (uint256)
{
if (_v == 0x0 && _r == 0x0 && _s == 0x0)
gasPriceLimit.validateGasPrice(tx.gasprice);
else
require(verifyTrustedSender(_path, _amount, _block, _for, _v, _r, _s));
// if ETH is provided, ensure that the amount is identical to _amount and verify that the source token is an ether token
IERC20Token fromToken = _path[0];
IERC20Token toToken;
(toToken, _amount) = convertByPath(_path, _amount, _minReturn, fromToken, _for);
// finished the conversion, transfer the funds to the target account
// if the target token is an ether token, withdraw the tokens and send them as ETH
// otherwise, transfer the tokens as is
if (etherTokens[toToken])
IEtherToken(toToken).withdrawTo(_for, _amount);
else
assert(toToken.transfer(_for, _amount));
return _amount;
}
/**
@dev executes the actual conversion by following the conversion path
@param _path conversion path, see conversion path format above
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@param _fromToken ERC20 token to convert from (the first element in the path)
@param _for account that will receive the conversion result
@return ERC20 token to convert to (the last element in the path) & tokens issued in return
*/
function convertByPath(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
IERC20Token _fromToken,
address _for
) private returns (IERC20Token, uint256) {
ISmartToken smartToken;
IERC20Token toToken;
IBancorConverter converter;
// get the contract features address from the registry
IContractFeatures features = IContractFeatures(registry.getAddress(ContractIds.CONTRACT_FEATURES));
// iterate over the conversion path
uint256 pathLength = _path.length;
for (uint256 i = 1; i < pathLength; i += 2) {
smartToken = ISmartToken(_path[i]);
toToken = _path[i + 1];
converter = IBancorConverter(smartToken.owner());
checkWhitelist(converter, _for, features);
// if the smart token isn't the source (from token), the converter doesn't have control over it and thus we need to approve the request
if (smartToken != _fromToken)
ensureAllowance(_fromToken, converter, _amount);
// make the conversion - if it's the last one, also provide the minimum return value
_amount = converter.change(_fromToken, toToken, _amount, i == pathLength - 2 ? _minReturn : 1);
_fromToken = toToken;
}
return (toToken, _amount);
}
/**
@dev checks whether the given converter supports a whitelist and if so, ensures that
the account that should receive the conversion result is actually whitelisted
@param _converter converter to check for whitelist
@param _for account that will receive the conversion result
@param _features contract features contract address
*/
function checkWhitelist(IBancorConverter _converter, address _for, IContractFeatures _features) private view {
IWhitelist whitelist;
// check if the converter supports the conversion whitelist feature
if (!_features.isSupported(_converter, FeatureIds.CONVERTER_CONVERSION_WHITELIST))
return;
// get the whitelist contract from the converter
whitelist = _converter.conversionWhitelist();
if (whitelist == address(0))
return;
// check if the account that should receive the conversion result is actually whitelisted
require(whitelist.isWhitelisted(_for));
}
/**
@dev claims the caller's tokens, converts them to any other token in the bancor network
by following a predefined conversion path and transfers the result tokens to a target account
note that allowance must be set beforehand
@param _path conversion path, see conversion path format above
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@param _for account that will receive the conversion result
@return tokens issued in return
*/
function claimAndConvertFor(IERC20Token[] _path, uint256 _amount, uint256 _minReturn, address _for) public returns (uint256) {
// we need to transfer the tokens from the caller to the converter before we follow
// the conversion path, to allow it to execute the conversion on behalf of the caller
// note: we assume we already have allowance
IERC20Token fromToken = _path[0];
assert(fromToken.transferFrom(msg.sender, this, _amount));
return convertFor(_path, _amount, _minReturn, _for);
}
/**
@dev converts the token to any other token in the bancor network by following
a predefined conversion path and transfers the result tokens back to the sender
note that the converter should already own the source tokens
@param _path conversion path, see conversion path format above
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return tokens issued in return
*/
function convert(IERC20Token[] _path, uint256 _amount, uint256 _minReturn) public payable returns (uint256) {
return convertFor(_path, _amount, _minReturn, msg.sender);
}
/**
@dev claims the caller's tokens, converts them to any other token in the bancor network
by following a predefined conversion path and transfers the result tokens back to the sender
note that allowance must be set beforehand
@param _path conversion path, see conversion path format above
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return tokens issued in return
*/
function claimAndConvert(IERC20Token[] _path, uint256 _amount, uint256 _minReturn) public returns (uint256) {
return claimAndConvertFor(_path, _amount, _minReturn, msg.sender);
}
/**
@dev utility, checks whether allowance for the given spender exists and approves one if it doesn't
@param _token token to check the allowance in
@param _spender approved address
@param _value allowance amount
*/
function ensureAllowance(IERC20Token _token, address _spender, uint256 _value) private {
// check if allowance for the given amount already exists
if (_token.allowance(this, _spender) >= _value)
return;
// if the allowance is nonzero, must reset it to 0 first
if (_token.allowance(this, _spender) != 0)
assert(_token.approve(_spender, 0));
// approve the new allowance
assert(_token.approve(_spender, _value));
}
// deprecated, backward compatibility
function convertForPrioritized(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
address _for,
uint256 _block,
uint256 _nonce,
uint8 _v,
bytes32 _r,
bytes32 _s)
public payable returns (uint256)
{
convertForPrioritized2(_path, _amount, _minReturn, _for, _block, _v, _r, _s);
}
}File 4 of 11: EtherToken
pragma solidity ^0.4.11;
/*
Utilities & Common Modifiers
*/
contract Utils {
/**
constructor
*/
function Utils() {
}
// verifies that an amount is greater than zero
modifier greaterThanZero(uint256 _amount) {
require(_amount > 0);
_;
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != 0x0);
_;
}
// verifies that the address is different than this contract address
modifier notThis(address _address) {
require(_address != address(this));
_;
}
// Overflow protected math functions
/**
@dev returns the sum of _x and _y, asserts if the calculation overflows
@param _x value 1
@param _y value 2
@return sum
*/
function safeAdd(uint256 _x, uint256 _y) internal returns (uint256) {
uint256 z = _x + _y;
assert(z >= _x);
return z;
}
/**
@dev returns the difference of _x minus _y, asserts if the subtraction results in a negative number
@param _x minuend
@param _y subtrahend
@return difference
*/
function safeSub(uint256 _x, uint256 _y) internal returns (uint256) {
assert(_x >= _y);
return _x - _y;
}
/**
@dev returns the product of multiplying _x by _y, asserts if the calculation overflows
@param _x factor 1
@param _y factor 2
@return product
*/
function safeMul(uint256 _x, uint256 _y) internal returns (uint256) {
uint256 z = _x * _y;
assert(_x == 0 || z / _x == _y);
return z;
}
}
/*
Owned contract interface
*/
contract IOwned {
// this function isn't abstract since the compiler emits automatically generated getter functions as external
function owner() public constant returns (address owner) { owner; }
function transferOwnership(address _newOwner) public;
function acceptOwnership() public;
}
/*
Provides support and utilities for contract ownership
*/
contract Owned is IOwned {
address public owner;
address public newOwner;
event OwnerUpdate(address _prevOwner, address _newOwner);
/**
@dev constructor
*/
function Owned() {
owner = msg.sender;
}
// allows execution by the owner only
modifier ownerOnly {
assert(msg.sender == owner);
_;
}
/**
@dev allows transferring the contract ownership
the new owner still needs to accept the transfer
can only be called by the contract owner
@param _newOwner new contract owner
*/
function transferOwnership(address _newOwner) public ownerOnly {
require(_newOwner != owner);
newOwner = _newOwner;
}
/**
@dev used by a new owner to accept an ownership transfer
*/
function acceptOwnership() public {
require(msg.sender == newOwner);
OwnerUpdate(owner, newOwner);
owner = newOwner;
newOwner = 0x0;
}
}
/*
Token Holder interface
*/
contract ITokenHolder is IOwned {
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount) public;
}
/*
We consider every contract to be a 'token holder' since it's currently not possible
for a contract to deny receiving tokens.
The TokenHolder's contract sole purpose is to provide a safety mechanism that allows
the owner to send tokens that were sent to the contract by mistake back to their sender.
*/
contract TokenHolder is ITokenHolder, Owned, Utils {
/**
@dev constructor
*/
function TokenHolder() {
}
/**
@dev withdraws tokens held by the contract and sends them to an account
can only be called by the owner
@param _token ERC20 token contract address
@param _to account to receive the new amount
@param _amount amount to withdraw
*/
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount)
public
ownerOnly
validAddress(_token)
validAddress(_to)
notThis(_to)
{
assert(_token.transfer(_to, _amount));
}
}
/*
ERC20 Standard Token interface
*/
contract IERC20Token {
// these functions aren't abstract since the compiler emits automatically generated getter functions as external
function name() public constant returns (string name) { name; }
function symbol() public constant returns (string symbol) { symbol; }
function decimals() public constant returns (uint8 decimals) { decimals; }
function totalSupply() public constant returns (uint256 totalSupply) { totalSupply; }
function balanceOf(address _owner) public constant returns (uint256 balance) { _owner; balance; }
function allowance(address _owner, address _spender) public constant returns (uint256 remaining) { _owner; _spender; remaining; }
function transfer(address _to, uint256 _value) public returns (bool success);
function transferFrom(address _from, address _to, uint256 _value) public returns (bool success);
function approve(address _spender, uint256 _value) public returns (bool success);
}
/**
ERC20 Standard Token implementation
*/
contract ERC20Token is IERC20Token, Utils {
string public standard = 'Token 0.1';
string public name = '';
string public symbol = '';
uint8 public decimals = 0;
uint256 public totalSupply = 0;
mapping (address => uint256) public balanceOf;
mapping (address => mapping (address => uint256)) public allowance;
event Transfer(address indexed _from, address indexed _to, uint256 _value);
event Approval(address indexed _owner, address indexed _spender, uint256 _value);
/**
@dev constructor
@param _name token name
@param _symbol token symbol
@param _decimals decimal points, for display purposes
*/
function ERC20Token(string _name, string _symbol, uint8 _decimals) {
require(bytes(_name).length > 0 && bytes(_symbol).length > 0); // validate input
name = _name;
symbol = _symbol;
decimals = _decimals;
}
/**
@dev send coins
throws on any error rather then return a false flag to minimize user errors
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transfer(address _to, uint256 _value)
public
validAddress(_to)
returns (bool success)
{
balanceOf[msg.sender] = safeSub(balanceOf[msg.sender], _value);
balanceOf[_to] = safeAdd(balanceOf[_to], _value);
Transfer(msg.sender, _to, _value);
return true;
}
/**
@dev an account/contract attempts to get the coins
throws on any error rather then return a false flag to minimize user errors
@param _from source address
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transferFrom(address _from, address _to, uint256 _value)
public
validAddress(_from)
validAddress(_to)
returns (bool success)
{
allowance[_from][msg.sender] = safeSub(allowance[_from][msg.sender], _value);
balanceOf[_from] = safeSub(balanceOf[_from], _value);
balanceOf[_to] = safeAdd(balanceOf[_to], _value);
Transfer(_from, _to, _value);
return true;
}
/**
@dev allow another account/contract to spend some tokens on your behalf
throws on any error rather then return a false flag to minimize user errors
also, to minimize the risk of the approve/transferFrom attack vector
(see https://docs.google.com/document/d/1YLPtQxZu1UAvO9cZ1O2RPXBbT0mooh4DYKjA_jp-RLM/), approve has to be called twice
in 2 separate transactions - once to change the allowance to 0 and secondly to change it to the new allowance value
@param _spender approved address
@param _value allowance amount
@return true if the approval was successful, false if it wasn't
*/
function approve(address _spender, uint256 _value)
public
validAddress(_spender)
returns (bool success)
{
// if the allowance isn't 0, it can only be updated to 0 to prevent an allowance change immediately after withdrawal
require(_value == 0 || allowance[msg.sender][_spender] == 0);
allowance[msg.sender][_spender] = _value;
Approval(msg.sender, _spender, _value);
return true;
}
}
/*
Ether Token interface
*/
contract IEtherToken is ITokenHolder, IERC20Token {
function deposit() public payable;
function withdraw(uint256 _amount) public;
function withdrawTo(address _to, uint256 _amount);
}
/**
Ether tokenization contract
'Owned' is specified here for readability reasons
*/
contract EtherToken is IEtherToken, Owned, ERC20Token, TokenHolder {
// triggered when the total supply is increased
event Issuance(uint256 _amount);
// triggered when the total supply is decreased
event Destruction(uint256 _amount);
/**
@dev constructor
*/
function EtherToken()
ERC20Token('Ether Token', 'ETH', 18) {
}
/**
@dev deposit ether in the account
*/
function deposit() public payable {
balanceOf[msg.sender] = safeAdd(balanceOf[msg.sender], msg.value); // add the value to the account balance
totalSupply = safeAdd(totalSupply, msg.value); // increase the total supply
Issuance(msg.value);
Transfer(this, msg.sender, msg.value);
}
/**
@dev withdraw ether from the account
@param _amount amount of ether to withdraw
*/
function withdraw(uint256 _amount) public {
withdrawTo(msg.sender, _amount);
}
/**
@dev withdraw ether from the account to a target account
@param _to account to receive the ether
@param _amount amount of ether to withdraw
*/
function withdrawTo(address _to, uint256 _amount)
public
notThis(_to)
{
balanceOf[msg.sender] = safeSub(balanceOf[msg.sender], _amount); // deduct the amount from the account balance
totalSupply = safeSub(totalSupply, _amount); // decrease the total supply
_to.transfer(_amount); // send the amount to the target account
Transfer(msg.sender, this, _amount);
Destruction(_amount);
}
// ERC20 standard method overrides with some extra protection
/**
@dev send coins
throws on any error rather then return a false flag to minimize user errors
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transfer(address _to, uint256 _value)
public
notThis(_to)
returns (bool success)
{
assert(super.transfer(_to, _value));
return true;
}
/**
@dev an account/contract attempts to get the coins
throws on any error rather then return a false flag to minimize user errors
@param _from source address
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transferFrom(address _from, address _to, uint256 _value)
public
notThis(_to)
returns (bool success)
{
assert(super.transferFrom(_from, _to, _value));
return true;
}
/**
@dev deposit ether in the account
*/
function() public payable {
deposit();
}
}File 5 of 11: ContractRegistry
pragma solidity ^0.4.23;
/*
Owned contract interface
*/
contract IOwned {
// this function isn't abstract since the compiler emits automatically generated getter functions as external
function owner() public view returns (address) {}
function transferOwnership(address _newOwner) public;
function acceptOwnership() public;
}
/*
Contract Registry interface
*/
contract IContractRegistry {
function addressOf(bytes32 _contractName) public view returns (address);
// deprecated, backward compatibility
function getAddress(bytes32 _contractName) public view returns (address);
}
/*
Utilities & Common Modifiers
*/
contract Utils {
/**
constructor
*/
constructor() public {
}
// verifies that an amount is greater than zero
modifier greaterThanZero(uint256 _amount) {
require(_amount > 0);
_;
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != address(0));
_;
}
// verifies that the address is different than this contract address
modifier notThis(address _address) {
require(_address != address(this));
_;
}
// Overflow protected math functions
/**
@dev returns the sum of _x and _y, asserts if the calculation overflows
@param _x value 1
@param _y value 2
@return sum
*/
function safeAdd(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x + _y;
assert(z >= _x);
return z;
}
/**
@dev returns the difference of _x minus _y, asserts if the subtraction results in a negative number
@param _x minuend
@param _y subtrahend
@return difference
*/
function safeSub(uint256 _x, uint256 _y) internal pure returns (uint256) {
assert(_x >= _y);
return _x - _y;
}
/**
@dev returns the product of multiplying _x by _y, asserts if the calculation overflows
@param _x factor 1
@param _y factor 2
@return product
*/
function safeMul(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x * _y;
assert(_x == 0 || z / _x == _y);
return z;
}
}
/*
Provides support and utilities for contract ownership
*/
contract Owned is IOwned {
address public owner;
address public newOwner;
event OwnerUpdate(address indexed _prevOwner, address indexed _newOwner);
/**
@dev constructor
*/
constructor() public {
owner = msg.sender;
}
// allows execution by the owner only
modifier ownerOnly {
assert(msg.sender == owner);
_;
}
/**
@dev allows transferring the contract ownership
the new owner still needs to accept the transfer
can only be called by the contract owner
@param _newOwner new contract owner
*/
function transferOwnership(address _newOwner) public ownerOnly {
require(_newOwner != owner);
newOwner = _newOwner;
}
/**
@dev used by a new owner to accept an ownership transfer
*/
function acceptOwnership() public {
require(msg.sender == newOwner);
emit OwnerUpdate(owner, newOwner);
owner = newOwner;
newOwner = address(0);
}
}
/**
Contract Registry
The contract registry keeps contract addresses by name.
The owner can update contract addresses so that a contract name always points to the latest version
of the given contract.
Other contracts can query the registry to get updated addresses instead of depending on specific
addresses.
Note that contract names are limited to 32 bytes UTF8 encoded ASCII strings to optimize gas costs
*/
contract ContractRegistry is IContractRegistry, Owned, Utils {
struct RegistryItem {
address contractAddress; // contract address
uint256 nameIndex; // index of the item in the list of contract names
bool isSet; // used to tell if the mapping element is defined
}
mapping (bytes32 => RegistryItem) private items; // name -> RegistryItem mapping
string[] public contractNames; // list of all registered contract names
// triggered when an address pointed to by a contract name is modified
event AddressUpdate(bytes32 indexed _contractName, address _contractAddress);
/**
@dev constructor
*/
constructor() public {
}
/**
@dev returns the number of items in the registry
@return number of items
*/
function itemCount() public view returns (uint256) {
return contractNames.length;
}
/**
@dev returns the address associated with the given contract name
@param _contractName contract name
@return contract address
*/
function addressOf(bytes32 _contractName) public view returns (address) {
return items[_contractName].contractAddress;
}
/**
@dev registers a new address for the contract name in the registry
@param _contractName contract name
@param _contractAddress contract address
*/
function registerAddress(bytes32 _contractName, address _contractAddress)
public
ownerOnly
validAddress(_contractAddress)
{
require(_contractName.length > 0); // validate input
// update the address in the registry
items[_contractName].contractAddress = _contractAddress;
if (!items[_contractName].isSet) {
// mark the item as set
items[_contractName].isSet = true;
// add the contract name to the name list
uint256 i = contractNames.push(bytes32ToString(_contractName));
// update the item's index in the list
items[_contractName].nameIndex = i - 1;
}
// dispatch the address update event
emit AddressUpdate(_contractName, _contractAddress);
}
/**
@dev removes an existing contract address from the registry
@param _contractName contract name
*/
function unregisterAddress(bytes32 _contractName) public ownerOnly {
require(_contractName.length > 0); // validate input
// remove the address from the registry
items[_contractName].contractAddress = address(0);
if (items[_contractName].isSet) {
// mark the item as empty
items[_contractName].isSet = false;
// if there are multiple items in the registry, move the last element to the deleted element's position
if (contractNames.length > 1)
contractNames[items[_contractName].nameIndex] = contractNames[contractNames.length - 1];
// remove the last element from the name list
contractNames.length--;
// zero the deleted element's index
items[_contractName].nameIndex = 0;
}
// dispatch the address update event
emit AddressUpdate(_contractName, address(0));
}
/**
@dev utility, converts bytes32 to a string
note that the bytes32 argument is assumed to be UTF8 encoded ASCII string
@return string representation of the given bytes32 argument
*/
function bytes32ToString(bytes32 _bytes) private pure returns (string) {
bytes memory byteArray = new bytes(32);
for (uint256 i; i < 32; i++) {
byteArray[i] = _bytes[i];
}
return string(byteArray);
}
// deprecated, backward compatibility
function getAddress(bytes32 _contractName) public view returns (address) {
return addressOf(_contractName);
}
}File 6 of 11: SmartToken
pragma solidity ^0.4.11;
/*
Overflow protected math functions
*/
contract SafeMath {
/**
constructor
*/
function SafeMath() {
}
/**
@dev returns the sum of _x and _y, asserts if the calculation overflows
@param _x value 1
@param _y value 2
@return sum
*/
function safeAdd(uint256 _x, uint256 _y) internal returns (uint256) {
uint256 z = _x + _y;
assert(z >= _x);
return z;
}
/**
@dev returns the difference of _x minus _y, asserts if the subtraction results in a negative number
@param _x minuend
@param _y subtrahend
@return difference
*/
function safeSub(uint256 _x, uint256 _y) internal returns (uint256) {
assert(_x >= _y);
return _x - _y;
}
/**
@dev returns the product of multiplying _x by _y, asserts if the calculation overflows
@param _x factor 1
@param _y factor 2
@return product
*/
function safeMul(uint256 _x, uint256 _y) internal returns (uint256) {
uint256 z = _x * _y;
assert(_x == 0 || z / _x == _y);
return z;
}
}
/*
Owned contract interface
*/
contract IOwned {
// this function isn't abstract since the compiler emits automatically generated getter functions as external
function owner() public constant returns (address owner) { owner; }
function transferOwnership(address _newOwner) public;
function acceptOwnership() public;
}
/*
Provides support and utilities for contract ownership
*/
contract Owned is IOwned {
address public owner;
address public newOwner;
event OwnerUpdate(address _prevOwner, address _newOwner);
/**
@dev constructor
*/
function Owned() {
owner = msg.sender;
}
// allows execution by the owner only
modifier ownerOnly {
assert(msg.sender == owner);
_;
}
/**
@dev allows transferring the contract ownership
the new owner still need to accept the transfer
can only be called by the contract owner
@param _newOwner new contract owner
*/
function transferOwnership(address _newOwner) public ownerOnly {
require(_newOwner != owner);
newOwner = _newOwner;
}
/**
@dev used by a new owner to accept an ownership transfer
*/
function acceptOwnership() public {
require(msg.sender == newOwner);
OwnerUpdate(owner, newOwner);
owner = newOwner;
newOwner = 0x0;
}
}
/*
Token Holder interface
*/
contract ITokenHolder is IOwned {
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount) public;
}
/*
We consider every contract to be a 'token holder' since it's currently not possible
for a contract to deny receiving tokens.
The TokenHolder's contract sole purpose is to provide a safety mechanism that allows
the owner to send tokens that were sent to the contract by mistake back to their sender.
*/
contract TokenHolder is ITokenHolder, Owned {
/**
@dev constructor
*/
function TokenHolder() {
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != 0x0);
_;
}
// verifies that the address is different than this contract address
modifier notThis(address _address) {
require(_address != address(this));
_;
}
/**
@dev withdraws tokens held by the contract and sends them to an account
can only be called by the owner
@param _token ERC20 token contract address
@param _to account to receive the new amount
@param _amount amount to withdraw
*/
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount)
public
ownerOnly
validAddress(_token)
validAddress(_to)
notThis(_to)
{
assert(_token.transfer(_to, _amount));
}
}
/*
ERC20 Standard Token interface
*/
contract IERC20Token {
// these functions aren't abstract since the compiler emits automatically generated getter functions as external
function name() public constant returns (string name) { name; }
function symbol() public constant returns (string symbol) { symbol; }
function decimals() public constant returns (uint8 decimals) { decimals; }
function totalSupply() public constant returns (uint256 totalSupply) { totalSupply; }
function balanceOf(address _owner) public constant returns (uint256 balance) { _owner; balance; }
function allowance(address _owner, address _spender) public constant returns (uint256 remaining) { _owner; _spender; remaining; }
function transfer(address _to, uint256 _value) public returns (bool success);
function transferFrom(address _from, address _to, uint256 _value) public returns (bool success);
function approve(address _spender, uint256 _value) public returns (bool success);
}
/**
ERC20 Standard Token implementation
*/
contract ERC20Token is IERC20Token, SafeMath {
string public standard = 'Token 0.1';
string public name = '';
string public symbol = '';
uint8 public decimals = 0;
uint256 public totalSupply = 0;
mapping (address => uint256) public balanceOf;
mapping (address => mapping (address => uint256)) public allowance;
event Transfer(address indexed _from, address indexed _to, uint256 _value);
event Approval(address indexed _owner, address indexed _spender, uint256 _value);
/**
@dev constructor
@param _name token name
@param _symbol token symbol
@param _decimals decimal points, for display purposes
*/
function ERC20Token(string _name, string _symbol, uint8 _decimals) {
require(bytes(_name).length > 0 && bytes(_symbol).length > 0); // validate input
name = _name;
symbol = _symbol;
decimals = _decimals;
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != 0x0);
_;
}
/**
@dev send coins
throws on any error rather then return a false flag to minimize user errors
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transfer(address _to, uint256 _value)
public
validAddress(_to)
returns (bool success)
{
balanceOf[msg.sender] = safeSub(balanceOf[msg.sender], _value);
balanceOf[_to] = safeAdd(balanceOf[_to], _value);
Transfer(msg.sender, _to, _value);
return true;
}
/**
@dev an account/contract attempts to get the coins
throws on any error rather then return a false flag to minimize user errors
@param _from source address
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transferFrom(address _from, address _to, uint256 _value)
public
validAddress(_from)
validAddress(_to)
returns (bool success)
{
allowance[_from][msg.sender] = safeSub(allowance[_from][msg.sender], _value);
balanceOf[_from] = safeSub(balanceOf[_from], _value);
balanceOf[_to] = safeAdd(balanceOf[_to], _value);
Transfer(_from, _to, _value);
return true;
}
/**
@dev allow another account/contract to spend some tokens on your behalf
throws on any error rather then return a false flag to minimize user errors
also, to minimize the risk of the approve/transferFrom attack vector
(see https://docs.google.com/document/d/1YLPtQxZu1UAvO9cZ1O2RPXBbT0mooh4DYKjA_jp-RLM/), approve has to be called twice
in 2 separate transactions - once to change the allowance to 0 and secondly to change it to the new allowance value
@param _spender approved address
@param _value allowance amount
@return true if the approval was successful, false if it wasn't
*/
function approve(address _spender, uint256 _value)
public
validAddress(_spender)
returns (bool success)
{
// if the allowance isn't 0, it can only be updated to 0 to prevent an allowance change immediately after withdrawal
require(_value == 0 || allowance[msg.sender][_spender] == 0);
allowance[msg.sender][_spender] = _value;
Approval(msg.sender, _spender, _value);
return true;
}
}
/*
Smart Token interface
*/
contract ISmartToken is ITokenHolder, IERC20Token {
function disableTransfers(bool _disable) public;
function issue(address _to, uint256 _amount) public;
function destroy(address _from, uint256 _amount) public;
}
/*
Smart Token v0.2
'Owned' is specified here for readability reasons
*/
contract SmartToken is ISmartToken, ERC20Token, Owned, TokenHolder {
string public version = '0.2';
bool public transfersEnabled = true; // true if transfer/transferFrom are enabled, false if not
// triggered when a smart token is deployed - the _token address is defined for forward compatibility, in case we want to trigger the event from a factory
event NewSmartToken(address _token);
// triggered when the total supply is increased
event Issuance(uint256 _amount);
// triggered when the total supply is decreased
event Destruction(uint256 _amount);
/**
@dev constructor
@param _name token name
@param _symbol token short symbol, 1-6 characters
@param _decimals for display purposes only
*/
function SmartToken(string _name, string _symbol, uint8 _decimals)
ERC20Token(_name, _symbol, _decimals)
{
require(bytes(_symbol).length <= 6); // validate input
NewSmartToken(address(this));
}
// allows execution only when transfers aren't disabled
modifier transfersAllowed {
assert(transfersEnabled);
_;
}
/**
@dev disables/enables transfers
can only be called by the contract owner
@param _disable true to disable transfers, false to enable them
*/
function disableTransfers(bool _disable) public ownerOnly {
transfersEnabled = !_disable;
}
/**
@dev increases the token supply and sends the new tokens to an account
can only be called by the contract owner
@param _to account to receive the new amount
@param _amount amount to increase the supply by
*/
function issue(address _to, uint256 _amount)
public
ownerOnly
validAddress(_to)
notThis(_to)
{
totalSupply = safeAdd(totalSupply, _amount);
balanceOf[_to] = safeAdd(balanceOf[_to], _amount);
Issuance(_amount);
Transfer(this, _to, _amount);
}
/**
@dev removes tokens from an account and decreases the token supply
can only be called by the contract owner
@param _from account to remove the amount from
@param _amount amount to decrease the supply by
*/
function destroy(address _from, uint256 _amount)
public
ownerOnly
{
balanceOf[_from] = safeSub(balanceOf[_from], _amount);
totalSupply = safeSub(totalSupply, _amount);
Transfer(_from, this, _amount);
Destruction(_amount);
}
// ERC20 standard method overrides with some extra functionality
/**
@dev send coins
throws on any error rather then return a false flag to minimize user errors
note that when transferring to the smart token's address, the coins are actually destroyed
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transfer(address _to, uint256 _value) public transfersAllowed returns (bool success) {
assert(super.transfer(_to, _value));
// transferring to the contract address destroys tokens
if (_to == address(this)) {
balanceOf[_to] -= _value;
totalSupply -= _value;
Destruction(_value);
}
return true;
}
/**
@dev an account/contract attempts to get the coins
throws on any error rather then return a false flag to minimize user errors
note that when transferring to the smart token's address, the coins are actually destroyed
@param _from source address
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transferFrom(address _from, address _to, uint256 _value) public transfersAllowed returns (bool success) {
assert(super.transferFrom(_from, _to, _value));
// transferring to the contract address destroys tokens
if (_to == address(this)) {
balanceOf[_to] -= _value;
totalSupply -= _value;
Destruction(_value);
}
return true;
}
}File 7 of 11: ContractFeatures
pragma solidity ^0.4.21;
/*
Contract Features interface
*/
contract IContractFeatures {
function isSupported(address _contract, uint256 _features) public view returns (bool);
function enableFeatures(uint256 _features, bool _enable) public;
}
/**
Contract Features
Generic contract that allows every contract on the blockchain to define which features it supports.
Other contracts can query this contract to find out whether a given contract on the
blockchain supports a certain feature.
Each contract type can define its own list of feature flags.
Features can be only enabled/disabled by the contract they are defined for.
Features should be defined by each contract type as bit flags, e.g. -
uint256 public constant FEATURE1 = 1 << 0;
uint256 public constant FEATURE2 = 1 << 1;
uint256 public constant FEATURE3 = 1 << 2;
...
*/
contract ContractFeatures is IContractFeatures {
mapping (address => uint256) private featureFlags;
event FeaturesAddition(address indexed _address, uint256 _features);
event FeaturesRemoval(address indexed _address, uint256 _features);
/**
@dev constructor
*/
function ContractFeatures() public {
}
/**
@dev returns true if a given contract supports the given feature(s), false if not
@param _contract contract address to check support for
@param _features feature(s) to check for
@return true if the contract supports the feature(s), false if not
*/
function isSupported(address _contract, uint256 _features) public view returns (bool) {
return (featureFlags[_contract] & _features) == _features;
}
/**
@dev allows a contract to enable/disable certain feature(s)
@param _features feature(s) to enable/disable
@param _enable true to enable the feature(s), false to disabled them
*/
function enableFeatures(uint256 _features, bool _enable) public {
if (_enable) {
if (isSupported(msg.sender, _features))
return;
featureFlags[msg.sender] |= _features;
emit FeaturesAddition(msg.sender, _features);
} else {
if (!isSupported(msg.sender, _features))
return;
featureFlags[msg.sender] &= ~_features;
emit FeaturesRemoval(msg.sender, _features);
}
}
}File 8 of 11: BancorFormula
pragma solidity ^0.4.21;
/*
Utilities & Common Modifiers
*/
contract Utils {
/**
constructor
*/
function Utils() public {
}
// verifies that an amount is greater than zero
modifier greaterThanZero(uint256 _amount) {
require(_amount > 0);
_;
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != address(0));
_;
}
// verifies that the address is different than this contract address
modifier notThis(address _address) {
require(_address != address(this));
_;
}
// Overflow protected math functions
/**
@dev returns the sum of _x and _y, asserts if the calculation overflows
@param _x value 1
@param _y value 2
@return sum
*/
function safeAdd(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x + _y;
assert(z >= _x);
return z;
}
/**
@dev returns the difference of _x minus _y, asserts if the subtraction results in a negative number
@param _x minuend
@param _y subtrahend
@return difference
*/
function safeSub(uint256 _x, uint256 _y) internal pure returns (uint256) {
assert(_x >= _y);
return _x - _y;
}
/**
@dev returns the product of multiplying _x by _y, asserts if the calculation overflows
@param _x factor 1
@param _y factor 2
@return product
*/
function safeMul(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x * _y;
assert(_x == 0 || z / _x == _y);
return z;
}
}
/*
Bancor Formula interface
*/
contract IBancorFormula {
function calculatePurchaseReturn(uint256 _supply, uint256 _connectorBalance, uint32 _connectorWeight, uint256 _depositAmount) public view returns (uint256);
function calculateSaleReturn(uint256 _supply, uint256 _connectorBalance, uint32 _connectorWeight, uint256 _sellAmount) public view returns (uint256);
function calculateCrossConnectorReturn(uint256 _fromConnectorBalance, uint32 _fromConnectorWeight, uint256 _toConnectorBalance, uint32 _toConnectorWeight, uint256 _amount) public view returns (uint256);
}
contract BancorFormula is IBancorFormula, Utils {
string public version = '0.3';
uint256 private constant ONE = 1;
uint32 private constant MAX_WEIGHT = 1000000;
uint8 private constant MIN_PRECISION = 32;
uint8 private constant MAX_PRECISION = 127;
/**
Auto-generated via 'PrintIntScalingFactors.py'
*/
uint256 private constant FIXED_1 = 0x080000000000000000000000000000000;
uint256 private constant FIXED_2 = 0x100000000000000000000000000000000;
uint256 private constant MAX_NUM = 0x200000000000000000000000000000000;
/**
Auto-generated via 'PrintLn2ScalingFactors.py'
*/
uint256 private constant LN2_NUMERATOR = 0x3f80fe03f80fe03f80fe03f80fe03f8;
uint256 private constant LN2_DENOMINATOR = 0x5b9de1d10bf4103d647b0955897ba80;
/**
Auto-generated via 'PrintFunctionOptimalLog.py' and 'PrintFunctionOptimalExp.py'
*/
uint256 private constant OPT_LOG_MAX_VAL = 0x15bf0a8b1457695355fb8ac404e7a79e3;
uint256 private constant OPT_EXP_MAX_VAL = 0x800000000000000000000000000000000;
/**
Auto-generated via 'PrintFunctionBancorFormula.py'
*/
uint256[128] private maxExpArray;
function BancorFormula() public {
// maxExpArray[ 0] = 0x6bffffffffffffffffffffffffffffffff;
// maxExpArray[ 1] = 0x67ffffffffffffffffffffffffffffffff;
// maxExpArray[ 2] = 0x637fffffffffffffffffffffffffffffff;
// maxExpArray[ 3] = 0x5f6fffffffffffffffffffffffffffffff;
// maxExpArray[ 4] = 0x5b77ffffffffffffffffffffffffffffff;
// maxExpArray[ 5] = 0x57b3ffffffffffffffffffffffffffffff;
// maxExpArray[ 6] = 0x5419ffffffffffffffffffffffffffffff;
// maxExpArray[ 7] = 0x50a2ffffffffffffffffffffffffffffff;
// maxExpArray[ 8] = 0x4d517fffffffffffffffffffffffffffff;
// maxExpArray[ 9] = 0x4a233fffffffffffffffffffffffffffff;
// maxExpArray[ 10] = 0x47165fffffffffffffffffffffffffffff;
// maxExpArray[ 11] = 0x4429afffffffffffffffffffffffffffff;
// maxExpArray[ 12] = 0x415bc7ffffffffffffffffffffffffffff;
// maxExpArray[ 13] = 0x3eab73ffffffffffffffffffffffffffff;
// maxExpArray[ 14] = 0x3c1771ffffffffffffffffffffffffffff;
// maxExpArray[ 15] = 0x399e96ffffffffffffffffffffffffffff;
// maxExpArray[ 16] = 0x373fc47fffffffffffffffffffffffffff;
// maxExpArray[ 17] = 0x34f9e8ffffffffffffffffffffffffffff;
// maxExpArray[ 18] = 0x32cbfd5fffffffffffffffffffffffffff;
// maxExpArray[ 19] = 0x30b5057fffffffffffffffffffffffffff;
// maxExpArray[ 20] = 0x2eb40f9fffffffffffffffffffffffffff;
// maxExpArray[ 21] = 0x2cc8340fffffffffffffffffffffffffff;
// maxExpArray[ 22] = 0x2af09481ffffffffffffffffffffffffff;
// maxExpArray[ 23] = 0x292c5bddffffffffffffffffffffffffff;
// maxExpArray[ 24] = 0x277abdcdffffffffffffffffffffffffff;
// maxExpArray[ 25] = 0x25daf6657fffffffffffffffffffffffff;
// maxExpArray[ 26] = 0x244c49c65fffffffffffffffffffffffff;
// maxExpArray[ 27] = 0x22ce03cd5fffffffffffffffffffffffff;
// maxExpArray[ 28] = 0x215f77c047ffffffffffffffffffffffff;
// maxExpArray[ 29] = 0x1fffffffffffffffffffffffffffffffff;
// maxExpArray[ 30] = 0x1eaefdbdabffffffffffffffffffffffff;
// maxExpArray[ 31] = 0x1d6bd8b2ebffffffffffffffffffffffff;
maxExpArray[ 32] = 0x1c35fedd14ffffffffffffffffffffffff;
maxExpArray[ 33] = 0x1b0ce43b323fffffffffffffffffffffff;
maxExpArray[ 34] = 0x19f0028ec1ffffffffffffffffffffffff;
maxExpArray[ 35] = 0x18ded91f0e7fffffffffffffffffffffff;
maxExpArray[ 36] = 0x17d8ec7f0417ffffffffffffffffffffff;
maxExpArray[ 37] = 0x16ddc6556cdbffffffffffffffffffffff;
maxExpArray[ 38] = 0x15ecf52776a1ffffffffffffffffffffff;
maxExpArray[ 39] = 0x15060c256cb2ffffffffffffffffffffff;
maxExpArray[ 40] = 0x1428a2f98d72ffffffffffffffffffffff;
maxExpArray[ 41] = 0x13545598e5c23fffffffffffffffffffff;
maxExpArray[ 42] = 0x1288c4161ce1dfffffffffffffffffffff;
maxExpArray[ 43] = 0x11c592761c666fffffffffffffffffffff;
maxExpArray[ 44] = 0x110a688680a757ffffffffffffffffffff;
maxExpArray[ 45] = 0x1056f1b5bedf77ffffffffffffffffffff;
maxExpArray[ 46] = 0x0faadceceeff8bffffffffffffffffffff;
maxExpArray[ 47] = 0x0f05dc6b27edadffffffffffffffffffff;
maxExpArray[ 48] = 0x0e67a5a25da4107fffffffffffffffffff;
maxExpArray[ 49] = 0x0dcff115b14eedffffffffffffffffffff;
maxExpArray[ 50] = 0x0d3e7a392431239fffffffffffffffffff;
maxExpArray[ 51] = 0x0cb2ff529eb71e4fffffffffffffffffff;
maxExpArray[ 52] = 0x0c2d415c3db974afffffffffffffffffff;
maxExpArray[ 53] = 0x0bad03e7d883f69bffffffffffffffffff;
maxExpArray[ 54] = 0x0b320d03b2c343d5ffffffffffffffffff;
maxExpArray[ 55] = 0x0abc25204e02828dffffffffffffffffff;
maxExpArray[ 56] = 0x0a4b16f74ee4bb207fffffffffffffffff;
maxExpArray[ 57] = 0x09deaf736ac1f569ffffffffffffffffff;
maxExpArray[ 58] = 0x0976bd9952c7aa957fffffffffffffffff;
maxExpArray[ 59] = 0x09131271922eaa606fffffffffffffffff;
maxExpArray[ 60] = 0x08b380f3558668c46fffffffffffffffff;
maxExpArray[ 61] = 0x0857ddf0117efa215bffffffffffffffff;
maxExpArray[ 62] = 0x07ffffffffffffffffffffffffffffffff;
maxExpArray[ 63] = 0x07abbf6f6abb9d087fffffffffffffffff;
maxExpArray[ 64] = 0x075af62cbac95f7dfa7fffffffffffffff;
maxExpArray[ 65] = 0x070d7fb7452e187ac13fffffffffffffff;
maxExpArray[ 66] = 0x06c3390ecc8af379295fffffffffffffff;
maxExpArray[ 67] = 0x067c00a3b07ffc01fd6fffffffffffffff;
maxExpArray[ 68] = 0x0637b647c39cbb9d3d27ffffffffffffff;
maxExpArray[ 69] = 0x05f63b1fc104dbd39587ffffffffffffff;
maxExpArray[ 70] = 0x05b771955b36e12f7235ffffffffffffff;
maxExpArray[ 71] = 0x057b3d49dda84556d6f6ffffffffffffff;
maxExpArray[ 72] = 0x054183095b2c8ececf30ffffffffffffff;
maxExpArray[ 73] = 0x050a28be635ca2b888f77fffffffffffff;
maxExpArray[ 74] = 0x04d5156639708c9db33c3fffffffffffff;
maxExpArray[ 75] = 0x04a23105873875bd52dfdfffffffffffff;
maxExpArray[ 76] = 0x0471649d87199aa990756fffffffffffff;
maxExpArray[ 77] = 0x04429a21a029d4c1457cfbffffffffffff;
maxExpArray[ 78] = 0x0415bc6d6fb7dd71af2cb3ffffffffffff;
maxExpArray[ 79] = 0x03eab73b3bbfe282243ce1ffffffffffff;
maxExpArray[ 80] = 0x03c1771ac9fb6b4c18e229ffffffffffff;
maxExpArray[ 81] = 0x0399e96897690418f785257fffffffffff;
maxExpArray[ 82] = 0x0373fc456c53bb779bf0ea9fffffffffff;
maxExpArray[ 83] = 0x034f9e8e490c48e67e6ab8bfffffffffff;
maxExpArray[ 84] = 0x032cbfd4a7adc790560b3337ffffffffff;
maxExpArray[ 85] = 0x030b50570f6e5d2acca94613ffffffffff;
maxExpArray[ 86] = 0x02eb40f9f620fda6b56c2861ffffffffff;
maxExpArray[ 87] = 0x02cc8340ecb0d0f520a6af58ffffffffff;
maxExpArray[ 88] = 0x02af09481380a0a35cf1ba02ffffffffff;
maxExpArray[ 89] = 0x0292c5bdd3b92ec810287b1b3fffffffff;
maxExpArray[ 90] = 0x0277abdcdab07d5a77ac6d6b9fffffffff;
maxExpArray[ 91] = 0x025daf6654b1eaa55fd64df5efffffffff;
maxExpArray[ 92] = 0x0244c49c648baa98192dce88b7ffffffff;
maxExpArray[ 93] = 0x022ce03cd5619a311b2471268bffffffff;
maxExpArray[ 94] = 0x0215f77c045fbe885654a44a0fffffffff;
maxExpArray[ 95] = 0x01ffffffffffffffffffffffffffffffff;
maxExpArray[ 96] = 0x01eaefdbdaaee7421fc4d3ede5ffffffff;
maxExpArray[ 97] = 0x01d6bd8b2eb257df7e8ca57b09bfffffff;
maxExpArray[ 98] = 0x01c35fedd14b861eb0443f7f133fffffff;
maxExpArray[ 99] = 0x01b0ce43b322bcde4a56e8ada5afffffff;
maxExpArray[100] = 0x019f0028ec1fff007f5a195a39dfffffff;
maxExpArray[101] = 0x018ded91f0e72ee74f49b15ba527ffffff;
maxExpArray[102] = 0x017d8ec7f04136f4e5615fd41a63ffffff;
maxExpArray[103] = 0x016ddc6556cdb84bdc8d12d22e6fffffff;
maxExpArray[104] = 0x015ecf52776a1155b5bd8395814f7fffff;
maxExpArray[105] = 0x015060c256cb23b3b3cc3754cf40ffffff;
maxExpArray[106] = 0x01428a2f98d728ae223ddab715be3fffff;
maxExpArray[107] = 0x013545598e5c23276ccf0ede68034fffff;
maxExpArray[108] = 0x01288c4161ce1d6f54b7f61081194fffff;
maxExpArray[109] = 0x011c592761c666aa641d5a01a40f17ffff;
maxExpArray[110] = 0x0110a688680a7530515f3e6e6cfdcdffff;
maxExpArray[111] = 0x01056f1b5bedf75c6bcb2ce8aed428ffff;
maxExpArray[112] = 0x00faadceceeff8a0890f3875f008277fff;
maxExpArray[113] = 0x00f05dc6b27edad306388a600f6ba0bfff;
maxExpArray[114] = 0x00e67a5a25da41063de1495d5b18cdbfff;
maxExpArray[115] = 0x00dcff115b14eedde6fc3aa5353f2e4fff;
maxExpArray[116] = 0x00d3e7a3924312399f9aae2e0f868f8fff;
maxExpArray[117] = 0x00cb2ff529eb71e41582cccd5a1ee26fff;
maxExpArray[118] = 0x00c2d415c3db974ab32a51840c0b67edff;
maxExpArray[119] = 0x00bad03e7d883f69ad5b0a186184e06bff;
maxExpArray[120] = 0x00b320d03b2c343d4829abd6075f0cc5ff;
maxExpArray[121] = 0x00abc25204e02828d73c6e80bcdb1a95bf;
maxExpArray[122] = 0x00a4b16f74ee4bb2040a1ec6c15fbbf2df;
maxExpArray[123] = 0x009deaf736ac1f569deb1b5ae3f36c130f;
maxExpArray[124] = 0x00976bd9952c7aa957f5937d790ef65037;
maxExpArray[125] = 0x009131271922eaa6064b73a22d0bd4f2bf;
maxExpArray[126] = 0x008b380f3558668c46c91c49a2f8e967b9;
maxExpArray[127] = 0x00857ddf0117efa215952912839f6473e6;
}
/**
@dev given a token supply, connector balance, weight and a deposit amount (in the connector token),
calculates the return for a given conversion (in the main token)
Formula:
Return = _supply * ((1 + _depositAmount / _connectorBalance) ^ (_connectorWeight / 1000000) - 1)
@param _supply token total supply
@param _connectorBalance total connector balance
@param _connectorWeight connector weight, represented in ppm, 1-1000000
@param _depositAmount deposit amount, in connector token
@return purchase return amount
*/
function calculatePurchaseReturn(uint256 _supply, uint256 _connectorBalance, uint32 _connectorWeight, uint256 _depositAmount) public view returns (uint256) {
// validate input
require(_supply > 0 && _connectorBalance > 0 && _connectorWeight > 0 && _connectorWeight <= MAX_WEIGHT);
// special case for 0 deposit amount
if (_depositAmount == 0)
return 0;
// special case if the weight = 100%
if (_connectorWeight == MAX_WEIGHT)
return safeMul(_supply, _depositAmount) / _connectorBalance;
uint256 result;
uint8 precision;
uint256 baseN = safeAdd(_depositAmount, _connectorBalance);
(result, precision) = power(baseN, _connectorBalance, _connectorWeight, MAX_WEIGHT);
uint256 temp = safeMul(_supply, result) >> precision;
return temp - _supply;
}
/**
@dev given a token supply, connector balance, weight and a sell amount (in the main token),
calculates the return for a given conversion (in the connector token)
Formula:
Return = _connectorBalance * (1 - (1 - _sellAmount / _supply) ^ (1 / (_connectorWeight / 1000000)))
@param _supply token total supply
@param _connectorBalance total connector
@param _connectorWeight constant connector Weight, represented in ppm, 1-1000000
@param _sellAmount sell amount, in the token itself
@return sale return amount
*/
function calculateSaleReturn(uint256 _supply, uint256 _connectorBalance, uint32 _connectorWeight, uint256 _sellAmount) public view returns (uint256) {
// validate input
require(_supply > 0 && _connectorBalance > 0 && _connectorWeight > 0 && _connectorWeight <= MAX_WEIGHT && _sellAmount <= _supply);
// special case for 0 sell amount
if (_sellAmount == 0)
return 0;
// special case for selling the entire supply
if (_sellAmount == _supply)
return _connectorBalance;
// special case if the weight = 100%
if (_connectorWeight == MAX_WEIGHT)
return safeMul(_connectorBalance, _sellAmount) / _supply;
uint256 result;
uint8 precision;
uint256 baseD = _supply - _sellAmount;
(result, precision) = power(_supply, baseD, MAX_WEIGHT, _connectorWeight);
uint256 temp1 = safeMul(_connectorBalance, result);
uint256 temp2 = _connectorBalance << precision;
return (temp1 - temp2) / result;
}
/**
@dev given two connector balances/weights and a sell amount (in the first connector token),
calculates the return for a conversion from the first connector token to the second connector token (in the second connector token)
Formula:
Return = _toConnectorBalance * (1 - (_fromConnectorBalance / (_fromConnectorBalance + _amount)) ^ (_fromConnectorWeight / _toConnectorWeight))
@param _fromConnectorBalance input connector balance
@param _fromConnectorWeight input connector weight, represented in ppm, 1-1000000
@param _toConnectorBalance output connector balance
@param _toConnectorWeight output connector weight, represented in ppm, 1-1000000
@param _amount input connector amount
@return second connector amount
*/
function calculateCrossConnectorReturn(uint256 _fromConnectorBalance, uint32 _fromConnectorWeight, uint256 _toConnectorBalance, uint32 _toConnectorWeight, uint256 _amount) public view returns (uint256) {
// validate input
require(_fromConnectorBalance > 0 && _fromConnectorWeight > 0 && _fromConnectorWeight <= MAX_WEIGHT && _toConnectorBalance > 0 && _toConnectorWeight > 0 && _toConnectorWeight <= MAX_WEIGHT);
// special case for equal weights
if (_fromConnectorWeight == _toConnectorWeight)
return safeMul(_toConnectorBalance, _amount) / safeAdd(_fromConnectorBalance, _amount);
uint256 result;
uint8 precision;
uint256 baseN = safeAdd(_fromConnectorBalance, _amount);
(result, precision) = power(baseN, _fromConnectorBalance, _fromConnectorWeight, _toConnectorWeight);
uint256 temp1 = safeMul(_toConnectorBalance, result);
uint256 temp2 = _toConnectorBalance << precision;
return (temp1 - temp2) / result;
}
/**
General Description:
Determine a value of precision.
Calculate an integer approximation of (_baseN / _baseD) ^ (_expN / _expD) * 2 ^ precision.
Return the result along with the precision used.
Detailed Description:
Instead of calculating "base ^ exp", we calculate "e ^ (log(base) * exp)".
The value of "log(base)" is represented with an integer slightly smaller than "log(base) * 2 ^ precision".
The larger "precision" is, the more accurately this value represents the real value.
However, the larger "precision" is, the more bits are required in order to store this value.
And the exponentiation function, which takes "x" and calculates "e ^ x", is limited to a maximum exponent (maximum value of "x").
This maximum exponent depends on the "precision" used, and it is given by "maxExpArray[precision] >> (MAX_PRECISION - precision)".
Hence we need to determine the highest precision which can be used for the given input, before calling the exponentiation function.
This allows us to compute "base ^ exp" with maximum accuracy and without exceeding 256 bits in any of the intermediate computations.
This functions assumes that "_expN < 2 ^ 256 / log(MAX_NUM - 1)", otherwise the multiplication should be replaced with a "safeMul".
*/
function power(uint256 _baseN, uint256 _baseD, uint32 _expN, uint32 _expD) internal view returns (uint256, uint8) {
assert(_baseN < MAX_NUM);
uint256 baseLog;
uint256 base = _baseN * FIXED_1 / _baseD;
if (base < OPT_LOG_MAX_VAL) {
baseLog = optimalLog(base);
}
else {
baseLog = generalLog(base);
}
uint256 baseLogTimesExp = baseLog * _expN / _expD;
if (baseLogTimesExp < OPT_EXP_MAX_VAL) {
return (optimalExp(baseLogTimesExp), MAX_PRECISION);
}
else {
uint8 precision = findPositionInMaxExpArray(baseLogTimesExp);
return (generalExp(baseLogTimesExp >> (MAX_PRECISION - precision), precision), precision);
}
}
/**
Compute log(x / FIXED_1) * FIXED_1.
This functions assumes that "x >= FIXED_1", because the output would be negative otherwise.
*/
function generalLog(uint256 x) internal pure returns (uint256) {
uint256 res = 0;
// If x >= 2, then we compute the integer part of log2(x), which is larger than 0.
if (x >= FIXED_2) {
uint8 count = floorLog2(x / FIXED_1);
x >>= count; // now x < 2
res = count * FIXED_1;
}
// If x > 1, then we compute the fraction part of log2(x), which is larger than 0.
if (x > FIXED_1) {
for (uint8 i = MAX_PRECISION; i > 0; --i) {
x = (x * x) / FIXED_1; // now 1 < x < 4
if (x >= FIXED_2) {
x >>= 1; // now 1 < x < 2
res += ONE << (i - 1);
}
}
}
return res * LN2_NUMERATOR / LN2_DENOMINATOR;
}
/**
Compute the largest integer smaller than or equal to the binary logarithm of the input.
*/
function floorLog2(uint256 _n) internal pure returns (uint8) {
uint8 res = 0;
if (_n < 256) {
// At most 8 iterations
while (_n > 1) {
_n >>= 1;
res += 1;
}
}
else {
// Exactly 8 iterations
for (uint8 s = 128; s > 0; s >>= 1) {
if (_n >= (ONE << s)) {
_n >>= s;
res |= s;
}
}
}
return res;
}
/**
The global "maxExpArray" is sorted in descending order, and therefore the following statements are equivalent:
- This function finds the position of [the smallest value in "maxExpArray" larger than or equal to "x"]
- This function finds the highest position of [a value in "maxExpArray" larger than or equal to "x"]
*/
function findPositionInMaxExpArray(uint256 _x) internal view returns (uint8) {
uint8 lo = MIN_PRECISION;
uint8 hi = MAX_PRECISION;
while (lo + 1 < hi) {
uint8 mid = (lo + hi) / 2;
if (maxExpArray[mid] >= _x)
lo = mid;
else
hi = mid;
}
if (maxExpArray[hi] >= _x)
return hi;
if (maxExpArray[lo] >= _x)
return lo;
assert(false);
return 0;
}
/**
This function can be auto-generated by the script 'PrintFunctionGeneralExp.py'.
It approximates "e ^ x" via maclaurin summation: "(x^0)/0! + (x^1)/1! + ... + (x^n)/n!".
It returns "e ^ (x / 2 ^ precision) * 2 ^ precision", that is, the result is upshifted for accuracy.
The global "maxExpArray" maps each "precision" to "((maximumExponent + 1) << (MAX_PRECISION - precision)) - 1".
The maximum permitted value for "x" is therefore given by "maxExpArray[precision] >> (MAX_PRECISION - precision)".
*/
function generalExp(uint256 _x, uint8 _precision) internal pure returns (uint256) {
uint256 xi = _x;
uint256 res = 0;
xi = (xi * _x) >> _precision; res += xi * 0x3442c4e6074a82f1797f72ac0000000; // add x^02 * (33! / 02!)
xi = (xi * _x) >> _precision; res += xi * 0x116b96f757c380fb287fd0e40000000; // add x^03 * (33! / 03!)
xi = (xi * _x) >> _precision; res += xi * 0x045ae5bdd5f0e03eca1ff4390000000; // add x^04 * (33! / 04!)
xi = (xi * _x) >> _precision; res += xi * 0x00defabf91302cd95b9ffda50000000; // add x^05 * (33! / 05!)
xi = (xi * _x) >> _precision; res += xi * 0x002529ca9832b22439efff9b8000000; // add x^06 * (33! / 06!)
xi = (xi * _x) >> _precision; res += xi * 0x00054f1cf12bd04e516b6da88000000; // add x^07 * (33! / 07!)
xi = (xi * _x) >> _precision; res += xi * 0x0000a9e39e257a09ca2d6db51000000; // add x^08 * (33! / 08!)
xi = (xi * _x) >> _precision; res += xi * 0x000012e066e7b839fa050c309000000; // add x^09 * (33! / 09!)
xi = (xi * _x) >> _precision; res += xi * 0x000001e33d7d926c329a1ad1a800000; // add x^10 * (33! / 10!)
xi = (xi * _x) >> _precision; res += xi * 0x0000002bee513bdb4a6b19b5f800000; // add x^11 * (33! / 11!)
xi = (xi * _x) >> _precision; res += xi * 0x00000003a9316fa79b88eccf2a00000; // add x^12 * (33! / 12!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000048177ebe1fa812375200000; // add x^13 * (33! / 13!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000005263fe90242dcbacf00000; // add x^14 * (33! / 14!)
xi = (xi * _x) >> _precision; res += xi * 0x000000000057e22099c030d94100000; // add x^15 * (33! / 15!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000000057e22099c030d9410000; // add x^16 * (33! / 16!)
xi = (xi * _x) >> _precision; res += xi * 0x00000000000052b6b54569976310000; // add x^17 * (33! / 17!)
xi = (xi * _x) >> _precision; res += xi * 0x00000000000004985f67696bf748000; // add x^18 * (33! / 18!)
xi = (xi * _x) >> _precision; res += xi * 0x000000000000003dea12ea99e498000; // add x^19 * (33! / 19!)
xi = (xi * _x) >> _precision; res += xi * 0x00000000000000031880f2214b6e000; // add x^20 * (33! / 20!)
xi = (xi * _x) >> _precision; res += xi * 0x000000000000000025bcff56eb36000; // add x^21 * (33! / 21!)
xi = (xi * _x) >> _precision; res += xi * 0x000000000000000001b722e10ab1000; // add x^22 * (33! / 22!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000000000000001317c70077000; // add x^23 * (33! / 23!)
xi = (xi * _x) >> _precision; res += xi * 0x00000000000000000000cba84aafa00; // add x^24 * (33! / 24!)
xi = (xi * _x) >> _precision; res += xi * 0x00000000000000000000082573a0a00; // add x^25 * (33! / 25!)
xi = (xi * _x) >> _precision; res += xi * 0x00000000000000000000005035ad900; // add x^26 * (33! / 26!)
xi = (xi * _x) >> _precision; res += xi * 0x000000000000000000000002f881b00; // add x^27 * (33! / 27!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000000000000000000001b29340; // add x^28 * (33! / 28!)
xi = (xi * _x) >> _precision; res += xi * 0x00000000000000000000000000efc40; // add x^29 * (33! / 29!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000000000000000000000007fe0; // add x^30 * (33! / 30!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000000000000000000000000420; // add x^31 * (33! / 31!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000000000000000000000000021; // add x^32 * (33! / 32!)
xi = (xi * _x) >> _precision; res += xi * 0x0000000000000000000000000000001; // add x^33 * (33! / 33!)
return res / 0x688589cc0e9505e2f2fee5580000000 + _x + (ONE << _precision); // divide by 33! and then add x^1 / 1! + x^0 / 0!
}
/**
Return log(x / FIXED_1) * FIXED_1
Input range: FIXED_1 <= x <= LOG_EXP_MAX_VAL - 1
Auto-generated via 'PrintFunctionOptimalLog.py'
*/
function optimalLog(uint256 x) internal pure returns (uint256) {
uint256 res = 0;
uint256 y;
uint256 z;
uint256 w;
if (x >= 0xd3094c70f034de4b96ff7d5b6f99fcd8) {res += 0x40000000000000000000000000000000; x = x * FIXED_1 / 0xd3094c70f034de4b96ff7d5b6f99fcd8;}
if (x >= 0xa45af1e1f40c333b3de1db4dd55f29a7) {res += 0x20000000000000000000000000000000; x = x * FIXED_1 / 0xa45af1e1f40c333b3de1db4dd55f29a7;}
if (x >= 0x910b022db7ae67ce76b441c27035c6a1) {res += 0x10000000000000000000000000000000; x = x * FIXED_1 / 0x910b022db7ae67ce76b441c27035c6a1;}
if (x >= 0x88415abbe9a76bead8d00cf112e4d4a8) {res += 0x08000000000000000000000000000000; x = x * FIXED_1 / 0x88415abbe9a76bead8d00cf112e4d4a8;}
if (x >= 0x84102b00893f64c705e841d5d4064bd3) {res += 0x04000000000000000000000000000000; x = x * FIXED_1 / 0x84102b00893f64c705e841d5d4064bd3;}
if (x >= 0x8204055aaef1c8bd5c3259f4822735a2) {res += 0x02000000000000000000000000000000; x = x * FIXED_1 / 0x8204055aaef1c8bd5c3259f4822735a2;}
if (x >= 0x810100ab00222d861931c15e39b44e99) {res += 0x01000000000000000000000000000000; x = x * FIXED_1 / 0x810100ab00222d861931c15e39b44e99;}
if (x >= 0x808040155aabbbe9451521693554f733) {res += 0x00800000000000000000000000000000; x = x * FIXED_1 / 0x808040155aabbbe9451521693554f733;}
z = y = x - FIXED_1;
w = y * y / FIXED_1;
res += z * (0x100000000000000000000000000000000 - y) / 0x100000000000000000000000000000000; z = z * w / FIXED_1;
res += z * (0x0aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa - y) / 0x200000000000000000000000000000000; z = z * w / FIXED_1;
res += z * (0x099999999999999999999999999999999 - y) / 0x300000000000000000000000000000000; z = z * w / FIXED_1;
res += z * (0x092492492492492492492492492492492 - y) / 0x400000000000000000000000000000000; z = z * w / FIXED_1;
res += z * (0x08e38e38e38e38e38e38e38e38e38e38e - y) / 0x500000000000000000000000000000000; z = z * w / FIXED_1;
res += z * (0x08ba2e8ba2e8ba2e8ba2e8ba2e8ba2e8b - y) / 0x600000000000000000000000000000000; z = z * w / FIXED_1;
res += z * (0x089d89d89d89d89d89d89d89d89d89d89 - y) / 0x700000000000000000000000000000000; z = z * w / FIXED_1;
res += z * (0x088888888888888888888888888888888 - y) / 0x800000000000000000000000000000000;
return res;
}
/**
Return e ^ (x / FIXED_1) * FIXED_1
Input range: 0 <= x <= OPT_EXP_MAX_VAL - 1
Auto-generated via 'PrintFunctionOptimalExp.py'
*/
function optimalExp(uint256 x) internal pure returns (uint256) {
uint256 res = 0;
uint256 y;
uint256 z;
z = y = x % 0x10000000000000000000000000000000;
z = z * y / FIXED_1; res += z * 0x10e1b3be415a0000; // add y^02 * (20! / 02!)
z = z * y / FIXED_1; res += z * 0x05a0913f6b1e0000; // add y^03 * (20! / 03!)
z = z * y / FIXED_1; res += z * 0x0168244fdac78000; // add y^04 * (20! / 04!)
z = z * y / FIXED_1; res += z * 0x004807432bc18000; // add y^05 * (20! / 05!)
z = z * y / FIXED_1; res += z * 0x000c0135dca04000; // add y^06 * (20! / 06!)
z = z * y / FIXED_1; res += z * 0x0001b707b1cdc000; // add y^07 * (20! / 07!)
z = z * y / FIXED_1; res += z * 0x000036e0f639b800; // add y^08 * (20! / 08!)
z = z * y / FIXED_1; res += z * 0x00000618fee9f800; // add y^09 * (20! / 09!)
z = z * y / FIXED_1; res += z * 0x0000009c197dcc00; // add y^10 * (20! / 10!)
z = z * y / FIXED_1; res += z * 0x0000000e30dce400; // add y^11 * (20! / 11!)
z = z * y / FIXED_1; res += z * 0x000000012ebd1300; // add y^12 * (20! / 12!)
z = z * y / FIXED_1; res += z * 0x0000000017499f00; // add y^13 * (20! / 13!)
z = z * y / FIXED_1; res += z * 0x0000000001a9d480; // add y^14 * (20! / 14!)
z = z * y / FIXED_1; res += z * 0x00000000001c6380; // add y^15 * (20! / 15!)
z = z * y / FIXED_1; res += z * 0x000000000001c638; // add y^16 * (20! / 16!)
z = z * y / FIXED_1; res += z * 0x0000000000001ab8; // add y^17 * (20! / 17!)
z = z * y / FIXED_1; res += z * 0x000000000000017c; // add y^18 * (20! / 18!)
z = z * y / FIXED_1; res += z * 0x0000000000000014; // add y^19 * (20! / 19!)
z = z * y / FIXED_1; res += z * 0x0000000000000001; // add y^20 * (20! / 20!)
res = res / 0x21c3677c82b40000 + y + FIXED_1; // divide by 20! and then add y^1 / 1! + y^0 / 0!
if ((x & 0x010000000000000000000000000000000) != 0) res = res * 0x1c3d6a24ed82218787d624d3e5eba95f9 / 0x18ebef9eac820ae8682b9793ac6d1e776;
if ((x & 0x020000000000000000000000000000000) != 0) res = res * 0x18ebef9eac820ae8682b9793ac6d1e778 / 0x1368b2fc6f9609fe7aceb46aa619baed4;
if ((x & 0x040000000000000000000000000000000) != 0) res = res * 0x1368b2fc6f9609fe7aceb46aa619baed5 / 0x0bc5ab1b16779be3575bd8f0520a9f21f;
if ((x & 0x080000000000000000000000000000000) != 0) res = res * 0x0bc5ab1b16779be3575bd8f0520a9f21e / 0x0454aaa8efe072e7f6ddbab84b40a55c9;
if ((x & 0x100000000000000000000000000000000) != 0) res = res * 0x0454aaa8efe072e7f6ddbab84b40a55c5 / 0x00960aadc109e7a3bf4578099615711ea;
if ((x & 0x200000000000000000000000000000000) != 0) res = res * 0x00960aadc109e7a3bf4578099615711d7 / 0x0002bf84208204f5977f9a8cf01fdce3d;
if ((x & 0x400000000000000000000000000000000) != 0) res = res * 0x0002bf84208204f5977f9a8cf01fdc307 / 0x0000003c6ab775dd0b95b4cbee7e65d11;
return res;
}
}File 9 of 11: SmartToken
pragma solidity ^0.4.11;
/*
Utilities & Common Modifiers
*/
contract Utils {
/**
constructor
*/
function Utils() {
}
// verifies that an amount is greater than zero
modifier greaterThanZero(uint256 _amount) {
require(_amount > 0);
_;
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != 0x0);
_;
}
// verifies that the address is different than this contract address
modifier notThis(address _address) {
require(_address != address(this));
_;
}
// Overflow protected math functions
/**
@dev returns the sum of _x and _y, asserts if the calculation overflows
@param _x value 1
@param _y value 2
@return sum
*/
function safeAdd(uint256 _x, uint256 _y) internal constant returns (uint256) {
uint256 z = _x + _y;
assert(z >= _x);
return z;
}
/**
@dev returns the difference of _x minus _y, asserts if the subtraction results in a negative number
@param _x minuend
@param _y subtrahend
@return difference
*/
function safeSub(uint256 _x, uint256 _y) internal constant returns (uint256) {
assert(_x >= _y);
return _x - _y;
}
/**
@dev returns the product of multiplying _x by _y, asserts if the calculation overflows
@param _x factor 1
@param _y factor 2
@return product
*/
function safeMul(uint256 _x, uint256 _y) internal constant returns (uint256) {
uint256 z = _x * _y;
assert(_x == 0 || z / _x == _y);
return z;
}
}
/*
Owned contract interface
*/
contract IOwned {
// this function isn't abstract since the compiler emits automatically generated getter functions as external
function owner() public constant returns (address) {}
function transferOwnership(address _newOwner) public;
function acceptOwnership() public;
}
/*
Provides support and utilities for contract ownership
*/
contract Owned is IOwned {
address public owner;
address public newOwner;
event OwnerUpdate(address _prevOwner, address _newOwner);
/**
@dev constructor
*/
function Owned() {
owner = msg.sender;
}
// allows execution by the owner only
modifier ownerOnly {
assert(msg.sender == owner);
_;
}
/**
@dev allows transferring the contract ownership
the new owner still needs to accept the transfer
can only be called by the contract owner
@param _newOwner new contract owner
*/
function transferOwnership(address _newOwner) public ownerOnly {
require(_newOwner != owner);
newOwner = _newOwner;
}
/**
@dev used by a new owner to accept an ownership transfer
*/
function acceptOwnership() public {
require(msg.sender == newOwner);
OwnerUpdate(owner, newOwner);
owner = newOwner;
newOwner = 0x0;
}
}
/*
ERC20 Standard Token interface
*/
contract IERC20Token {
// these functions aren't abstract since the compiler emits automatically generated getter functions as external
function name() public constant returns (string) {}
function symbol() public constant returns (string) {}
function decimals() public constant returns (uint8) {}
function totalSupply() public constant returns (uint256) {}
function balanceOf(address _owner) public constant returns (uint256) { _owner; }
function allowance(address _owner, address _spender) public constant returns (uint256) { _owner; _spender; }
function transfer(address _to, uint256 _value) public returns (bool success);
function transferFrom(address _from, address _to, uint256 _value) public returns (bool success);
function approve(address _spender, uint256 _value) public returns (bool success);
}
/**
ERC20 Standard Token implementation
*/
contract ERC20Token is IERC20Token, Utils {
string public standard = 'Token 0.1';
string public name = '';
string public symbol = '';
uint8 public decimals = 0;
uint256 public totalSupply = 0;
mapping (address => uint256) public balanceOf;
mapping (address => mapping (address => uint256)) public allowance;
event Transfer(address indexed _from, address indexed _to, uint256 _value);
event Approval(address indexed _owner, address indexed _spender, uint256 _value);
/**
@dev constructor
@param _name token name
@param _symbol token symbol
@param _decimals decimal points, for display purposes
*/
function ERC20Token(string _name, string _symbol, uint8 _decimals) {
require(bytes(_name).length > 0 && bytes(_symbol).length > 0); // validate input
name = _name;
symbol = _symbol;
decimals = _decimals;
}
/**
@dev send coins
throws on any error rather then return a false flag to minimize user errors
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transfer(address _to, uint256 _value)
public
validAddress(_to)
returns (bool success)
{
balanceOf[msg.sender] = safeSub(balanceOf[msg.sender], _value);
balanceOf[_to] = safeAdd(balanceOf[_to], _value);
Transfer(msg.sender, _to, _value);
return true;
}
/**
@dev an account/contract attempts to get the coins
throws on any error rather then return a false flag to minimize user errors
@param _from source address
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transferFrom(address _from, address _to, uint256 _value)
public
validAddress(_from)
validAddress(_to)
returns (bool success)
{
allowance[_from][msg.sender] = safeSub(allowance[_from][msg.sender], _value);
balanceOf[_from] = safeSub(balanceOf[_from], _value);
balanceOf[_to] = safeAdd(balanceOf[_to], _value);
Transfer(_from, _to, _value);
return true;
}
/**
@dev allow another account/contract to spend some tokens on your behalf
throws on any error rather then return a false flag to minimize user errors
also, to minimize the risk of the approve/transferFrom attack vector
(see https://docs.google.com/document/d/1YLPtQxZu1UAvO9cZ1O2RPXBbT0mooh4DYKjA_jp-RLM/), approve has to be called twice
in 2 separate transactions - once to change the allowance to 0 and secondly to change it to the new allowance value
@param _spender approved address
@param _value allowance amount
@return true if the approval was successful, false if it wasn't
*/
function approve(address _spender, uint256 _value)
public
validAddress(_spender)
returns (bool success)
{
// if the allowance isn't 0, it can only be updated to 0 to prevent an allowance change immediately after withdrawal
require(_value == 0 || allowance[msg.sender][_spender] == 0);
allowance[msg.sender][_spender] = _value;
Approval(msg.sender, _spender, _value);
return true;
}
}
/*
Token Holder interface
*/
contract ITokenHolder is IOwned {
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount) public;
}
/*
We consider every contract to be a 'token holder' since it's currently not possible
for a contract to deny receiving tokens.
The TokenHolder's contract sole purpose is to provide a safety mechanism that allows
the owner to send tokens that were sent to the contract by mistake back to their sender.
*/
contract TokenHolder is ITokenHolder, Owned, Utils {
/**
@dev constructor
*/
function TokenHolder() {
}
/**
@dev withdraws tokens held by the contract and sends them to an account
can only be called by the owner
@param _token ERC20 token contract address
@param _to account to receive the new amount
@param _amount amount to withdraw
*/
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount)
public
ownerOnly
validAddress(_token)
validAddress(_to)
notThis(_to)
{
assert(_token.transfer(_to, _amount));
}
}
/*
Smart Token interface
*/
contract ISmartToken is IOwned, IERC20Token {
function disableTransfers(bool _disable) public;
function issue(address _to, uint256 _amount) public;
function destroy(address _from, uint256 _amount) public;
}
/*
Smart Token v0.3
'Owned' is specified here for readability reasons
*/
contract SmartToken is ISmartToken, Owned, ERC20Token, TokenHolder {
string public version = '0.3';
bool public transfersEnabled = true; // true if transfer/transferFrom are enabled, false if not
// triggered when a smart token is deployed - the _token address is defined for forward compatibility, in case we want to trigger the event from a factory
event NewSmartToken(address _token);
// triggered when the total supply is increased
event Issuance(uint256 _amount);
// triggered when the total supply is decreased
event Destruction(uint256 _amount);
/**
@dev constructor
@param _name token name
@param _symbol token short symbol, minimum 1 character
@param _decimals for display purposes only
*/
function SmartToken(string _name, string _symbol, uint8 _decimals)
ERC20Token(_name, _symbol, _decimals)
{
NewSmartToken(address(this));
}
// allows execution only when transfers aren't disabled
modifier transfersAllowed {
assert(transfersEnabled);
_;
}
/**
@dev disables/enables transfers
can only be called by the contract owner
@param _disable true to disable transfers, false to enable them
*/
function disableTransfers(bool _disable) public ownerOnly {
transfersEnabled = !_disable;
}
/**
@dev increases the token supply and sends the new tokens to an account
can only be called by the contract owner
@param _to account to receive the new amount
@param _amount amount to increase the supply by
*/
function issue(address _to, uint256 _amount)
public
ownerOnly
validAddress(_to)
notThis(_to)
{
totalSupply = safeAdd(totalSupply, _amount);
balanceOf[_to] = safeAdd(balanceOf[_to], _amount);
Issuance(_amount);
Transfer(this, _to, _amount);
}
/**
@dev removes tokens from an account and decreases the token supply
can be called by the contract owner to destroy tokens from any account or by any holder to destroy tokens from his/her own account
@param _from account to remove the amount from
@param _amount amount to decrease the supply by
*/
function destroy(address _from, uint256 _amount) public {
require(msg.sender == _from || msg.sender == owner); // validate input
balanceOf[_from] = safeSub(balanceOf[_from], _amount);
totalSupply = safeSub(totalSupply, _amount);
Transfer(_from, this, _amount);
Destruction(_amount);
}
// ERC20 standard method overrides with some extra functionality
/**
@dev send coins
throws on any error rather then return a false flag to minimize user errors
in addition to the standard checks, the function throws if transfers are disabled
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transfer(address _to, uint256 _value) public transfersAllowed returns (bool success) {
assert(super.transfer(_to, _value));
return true;
}
/**
@dev an account/contract attempts to get the coins
throws on any error rather then return a false flag to minimize user errors
in addition to the standard checks, the function throws if transfers are disabled
@param _from source address
@param _to target address
@param _value transfer amount
@return true if the transfer was successful, false if it wasn't
*/
function transferFrom(address _from, address _to, uint256 _value) public transfersAllowed returns (bool success) {
assert(super.transferFrom(_from, _to, _value));
return true;
}
}File 10 of 11: BancorConverter
pragma solidity ^0.4.21;
/*
Owned contract interface
*/
contract IOwned {
// this function isn't abstract since the compiler emits automatically generated getter functions as external
function owner() public view returns (address) {}
function transferOwnership(address _newOwner) public;
function acceptOwnership() public;
}
/*
ERC20 Standard Token interface
*/
contract IERC20Token {
// these functions aren't abstract since the compiler emits automatically generated getter functions as external
function name() public view returns (string) {}
function symbol() public view returns (string) {}
function decimals() public view returns (uint8) {}
function totalSupply() public view returns (uint256) {}
function balanceOf(address _owner) public view returns (uint256) { _owner; }
function allowance(address _owner, address _spender) public view returns (uint256) { _owner; _spender; }
function transfer(address _to, uint256 _value) public returns (bool success);
function transferFrom(address _from, address _to, uint256 _value) public returns (bool success);
function approve(address _spender, uint256 _value) public returns (bool success);
}
/*
Smart Token interface
*/
contract ISmartToken is IOwned, IERC20Token {
function disableTransfers(bool _disable) public;
function issue(address _to, uint256 _amount) public;
function destroy(address _from, uint256 _amount) public;
}
/*
Contract Registry interface
*/
contract IContractRegistry {
function getAddress(bytes32 _contractName) public view returns (address);
}
/*
Contract Features interface
*/
contract IContractFeatures {
function isSupported(address _contract, uint256 _features) public view returns (bool);
function enableFeatures(uint256 _features, bool _enable) public;
}
/*
Whitelist interface
*/
contract IWhitelist {
function isWhitelisted(address _address) public view returns (bool);
}
/*
Token Holder interface
*/
contract ITokenHolder is IOwned {
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount) public;
}
/*
Bancor Formula interface
*/
contract IBancorFormula {
function calculatePurchaseReturn(uint256 _supply, uint256 _connectorBalance, uint32 _connectorWeight, uint256 _depositAmount) public view returns (uint256);
function calculateSaleReturn(uint256 _supply, uint256 _connectorBalance, uint32 _connectorWeight, uint256 _sellAmount) public view returns (uint256);
function calculateCrossConnectorReturn(uint256 _fromConnectorBalance, uint32 _fromConnectorWeight, uint256 _toConnectorBalance, uint32 _toConnectorWeight, uint256 _amount) public view returns (uint256);
}
/*
Bancor Converter interface
*/
contract IBancorConverter {
function getReturn(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount) public view returns (uint256);
function convert(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256);
function conversionWhitelist() public view returns (IWhitelist) {}
// deprecated, backward compatibility
function change(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256);
}
/*
Bancor Network interface
*/
contract IBancorNetwork {
function convert(IERC20Token[] _path, uint256 _amount, uint256 _minReturn) public payable returns (uint256);
function convertFor(IERC20Token[] _path, uint256 _amount, uint256 _minReturn, address _for) public payable returns (uint256);
function convertForPrioritized2(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
address _for,
uint256 _block,
uint8 _v,
bytes32 _r,
bytes32 _s)
public payable returns (uint256);
// deprecated, backward compatibility
function convertForPrioritized(
IERC20Token[] _path,
uint256 _amount,
uint256 _minReturn,
address _for,
uint256 _block,
uint256 _nonce,
uint8 _v,
bytes32 _r,
bytes32 _s)
public payable returns (uint256);
}
/*
Utilities & Common Modifiers
*/
contract Utils {
/**
constructor
*/
function Utils() public {
}
// verifies that an amount is greater than zero
modifier greaterThanZero(uint256 _amount) {
require(_amount > 0);
_;
}
// validates an address - currently only checks that it isn't null
modifier validAddress(address _address) {
require(_address != address(0));
_;
}
// verifies that the address is different than this contract address
modifier notThis(address _address) {
require(_address != address(this));
_;
}
// Overflow protected math functions
/**
@dev returns the sum of _x and _y, asserts if the calculation overflows
@param _x value 1
@param _y value 2
@return sum
*/
function safeAdd(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x + _y;
assert(z >= _x);
return z;
}
/**
@dev returns the difference of _x minus _y, asserts if the subtraction results in a negative number
@param _x minuend
@param _y subtrahend
@return difference
*/
function safeSub(uint256 _x, uint256 _y) internal pure returns (uint256) {
assert(_x >= _y);
return _x - _y;
}
/**
@dev returns the product of multiplying _x by _y, asserts if the calculation overflows
@param _x factor 1
@param _y factor 2
@return product
*/
function safeMul(uint256 _x, uint256 _y) internal pure returns (uint256) {
uint256 z = _x * _y;
assert(_x == 0 || z / _x == _y);
return z;
}
}
/*
Provides support and utilities for contract ownership
*/
contract Owned is IOwned {
address public owner;
address public newOwner;
event OwnerUpdate(address indexed _prevOwner, address indexed _newOwner);
/**
@dev constructor
*/
function Owned() public {
owner = msg.sender;
}
// allows execution by the owner only
modifier ownerOnly {
assert(msg.sender == owner);
_;
}
/**
@dev allows transferring the contract ownership
the new owner still needs to accept the transfer
can only be called by the contract owner
@param _newOwner new contract owner
*/
function transferOwnership(address _newOwner) public ownerOnly {
require(_newOwner != owner);
newOwner = _newOwner;
}
/**
@dev used by a new owner to accept an ownership transfer
*/
function acceptOwnership() public {
require(msg.sender == newOwner);
emit OwnerUpdate(owner, newOwner);
owner = newOwner;
newOwner = address(0);
}
}
/*
Provides support and utilities for contract management
Note that a managed contract must also have an owner
*/
contract Managed is Owned {
address public manager;
address public newManager;
event ManagerUpdate(address indexed _prevManager, address indexed _newManager);
/**
@dev constructor
*/
function Managed() public {
manager = msg.sender;
}
// allows execution by the manager only
modifier managerOnly {
assert(msg.sender == manager);
_;
}
// allows execution by either the owner or the manager only
modifier ownerOrManagerOnly {
require(msg.sender == owner || msg.sender == manager);
_;
}
/**
@dev allows transferring the contract management
the new manager still needs to accept the transfer
can only be called by the contract manager
@param _newManager new contract manager
*/
function transferManagement(address _newManager) public ownerOrManagerOnly {
require(_newManager != manager);
newManager = _newManager;
}
/**
@dev used by a new manager to accept a management transfer
*/
function acceptManagement() public {
require(msg.sender == newManager);
emit ManagerUpdate(manager, newManager);
manager = newManager;
newManager = address(0);
}
}
/**
Id definitions for bancor contracts
Can be used in conjunction with the contract registry to get contract addresses
*/
contract ContractIds {
// generic
bytes32 public constant CONTRACT_FEATURES = "ContractFeatures";
// bancor logic
bytes32 public constant BANCOR_NETWORK = "BancorNetwork";
bytes32 public constant BANCOR_FORMULA = "BancorFormula";
bytes32 public constant BANCOR_GAS_PRICE_LIMIT = "BancorGasPriceLimit";
bytes32 public constant BANCOR_CONVERTER_FACTORY = "BancorConverterFactory";
bytes32 public constant BANCOR_CONVERTER_UPGRADER = "BancorConverterUpgrader";
// tokens
bytes32 public constant BNT_TOKEN = "BNTToken";
}
/**
Id definitions for bancor contract features
Can be used to query the ContractFeatures contract to check whether a certain feature is supported by a contract
*/
contract FeatureIds {
// converter features
uint256 public constant CONVERTER_CONVERSION_WHITELIST = 1 << 0;
}
/*
We consider every contract to be a 'token holder' since it's currently not possible
for a contract to deny receiving tokens.
The TokenHolder's contract sole purpose is to provide a safety mechanism that allows
the owner to send tokens that were sent to the contract by mistake back to their sender.
*/
contract TokenHolder is ITokenHolder, Owned, Utils {
/**
@dev constructor
*/
function TokenHolder() public {
}
/**
@dev withdraws tokens held by the contract and sends them to an account
can only be called by the owner
@param _token ERC20 token contract address
@param _to account to receive the new amount
@param _amount amount to withdraw
*/
function withdrawTokens(IERC20Token _token, address _to, uint256 _amount)
public
ownerOnly
validAddress(_token)
validAddress(_to)
notThis(_to)
{
assert(_token.transfer(_to, _amount));
}
}
/*
The smart token controller is an upgradable part of the smart token that allows
more functionality as well as fixes for bugs/exploits.
Once it accepts ownership of the token, it becomes the token's sole controller
that can execute any of its functions.
To upgrade the controller, ownership must be transferred to a new controller, along with
any relevant data.
The smart token must be set on construction and cannot be changed afterwards.
Wrappers are provided (as opposed to a single 'execute' function) for each of the token's functions, for easier access.
Note that the controller can transfer token ownership to a new controller that
doesn't allow executing any function on the token, for a trustless solution.
Doing that will also remove the owner's ability to upgrade the controller.
*/
contract SmartTokenController is TokenHolder {
ISmartToken public token; // smart token
/**
@dev constructor
*/
function SmartTokenController(ISmartToken _token)
public
validAddress(_token)
{
token = _token;
}
// ensures that the controller is the token's owner
modifier active() {
assert(token.owner() == address(this));
_;
}
// ensures that the controller is not the token's owner
modifier inactive() {
assert(token.owner() != address(this));
_;
}
/**
@dev allows transferring the token ownership
the new owner still need to accept the transfer
can only be called by the contract owner
@param _newOwner new token owner
*/
function transferTokenOwnership(address _newOwner) public ownerOnly {
token.transferOwnership(_newOwner);
}
/**
@dev used by a new owner to accept a token ownership transfer
can only be called by the contract owner
*/
function acceptTokenOwnership() public ownerOnly {
token.acceptOwnership();
}
/**
@dev disables/enables token transfers
can only be called by the contract owner
@param _disable true to disable transfers, false to enable them
*/
function disableTokenTransfers(bool _disable) public ownerOnly {
token.disableTransfers(_disable);
}
/**
@dev withdraws tokens held by the controller and sends them to an account
can only be called by the owner
@param _token ERC20 token contract address
@param _to account to receive the new amount
@param _amount amount to withdraw
*/
function withdrawFromToken(
IERC20Token _token,
address _to,
uint256 _amount
)
public
ownerOnly
{
ITokenHolder(token).withdrawTokens(_token, _to, _amount);
}
}
/*
Bancor Converter v0.9
The Bancor version of the token converter, allows conversion between a smart token and other ERC20 tokens and between different ERC20 tokens and themselves.
ERC20 connector balance can be virtual, meaning that the calculations are based on the virtual balance instead of relying on
the actual connector balance. This is a security mechanism that prevents the need to keep a very large (and valuable) balance in a single contract.
The converter is upgradable (just like any SmartTokenController).
WARNING: It is NOT RECOMMENDED to use the converter with Smart Tokens that have less than 8 decimal digits
or with very small numbers because of precision loss
Open issues:
- Front-running attacks are currently mitigated by the following mechanisms:
- minimum return argument for each conversion provides a way to define a minimum/maximum price for the transaction
- gas price limit prevents users from having control over the order of execution
- gas price limit check can be skipped if the transaction comes from a trusted, whitelisted signer
Other potential solutions might include a commit/reveal based schemes
- Possibly add getters for the connector fields so that the client won't need to rely on the order in the struct
*/
contract BancorConverter is IBancorConverter, SmartTokenController, Managed, ContractIds, FeatureIds {
uint32 private constant MAX_WEIGHT = 1000000;
uint64 private constant MAX_CONVERSION_FEE = 1000000;
struct Connector {
uint256 virtualBalance; // connector virtual balance
uint32 weight; // connector weight, represented in ppm, 1-1000000
bool isVirtualBalanceEnabled; // true if virtual balance is enabled, false if not
bool isPurchaseEnabled; // is purchase of the smart token enabled with the connector, can be set by the owner
bool isSet; // used to tell if the mapping element is defined
}
string public version = '0.9';
string public converterType = 'bancor';
IContractRegistry public registry; // contract registry contract
IWhitelist public conversionWhitelist; // whitelist contract with list of addresses that are allowed to use the converter
IERC20Token[] public connectorTokens; // ERC20 standard token addresses
IERC20Token[] public quickBuyPath; // conversion path that's used in order to buy the token with ETH
mapping (address => Connector) public connectors; // connector token addresses -> connector data
uint32 private totalConnectorWeight = 0; // used to efficiently prevent increasing the total connector weight above 100%
uint32 public maxConversionFee = 0; // maximum conversion fee for the lifetime of the contract,
// represented in ppm, 0...1000000 (0 = no fee, 100 = 0.01%, 1000000 = 100%)
uint32 public conversionFee = 0; // current conversion fee, represented in ppm, 0...maxConversionFee
bool public conversionsEnabled = true; // true if token conversions is enabled, false if not
IERC20Token[] private convertPath;
// triggered when a conversion between two tokens occurs
event Conversion(
address indexed _fromToken,
address indexed _toToken,
address indexed _trader,
uint256 _amount,
uint256 _return,
int256 _conversionFee
);
// triggered after a conversion with new price data
event PriceDataUpdate(
address indexed _connectorToken,
uint256 _tokenSupply,
uint256 _connectorBalance,
uint32 _connectorWeight
);
// triggered when the conversion fee is updated
event ConversionFeeUpdate(uint32 _prevFee, uint32 _newFee);
/**
@dev constructor
@param _token smart token governed by the converter
@param _registry address of a contract registry contract
@param _maxConversionFee maximum conversion fee, represented in ppm
@param _connectorToken optional, initial connector, allows defining the first connector at deployment time
@param _connectorWeight optional, weight for the initial connector
*/
function BancorConverter(
ISmartToken _token,
IContractRegistry _registry,
uint32 _maxConversionFee,
IERC20Token _connectorToken,
uint32 _connectorWeight
)
public
SmartTokenController(_token)
validAddress(_registry)
validMaxConversionFee(_maxConversionFee)
{
registry = _registry;
IContractFeatures features = IContractFeatures(registry.getAddress(ContractIds.CONTRACT_FEATURES));
// initialize supported features
if (features != address(0))
features.enableFeatures(FeatureIds.CONVERTER_CONVERSION_WHITELIST, true);
maxConversionFee = _maxConversionFee;
if (_connectorToken != address(0))
addConnector(_connectorToken, _connectorWeight, false);
}
// validates a connector token address - verifies that the address belongs to one of the connector tokens
modifier validConnector(IERC20Token _address) {
require(connectors[_address].isSet);
_;
}
// validates a token address - verifies that the address belongs to one of the convertible tokens
modifier validToken(IERC20Token _address) {
require(_address == token || connectors[_address].isSet);
_;
}
// validates maximum conversion fee
modifier validMaxConversionFee(uint32 _conversionFee) {
require(_conversionFee >= 0 && _conversionFee <= MAX_CONVERSION_FEE);
_;
}
// validates conversion fee
modifier validConversionFee(uint32 _conversionFee) {
require(_conversionFee >= 0 && _conversionFee <= maxConversionFee);
_;
}
// validates connector weight range
modifier validConnectorWeight(uint32 _weight) {
require(_weight > 0 && _weight <= MAX_WEIGHT);
_;
}
// validates a conversion path - verifies that the number of elements is odd and that maximum number of 'hops' is 10
modifier validConversionPath(IERC20Token[] _path) {
require(_path.length > 2 && _path.length <= (1 + 2 * 10) && _path.length % 2 == 1);
_;
}
// allows execution only when conversions aren't disabled
modifier conversionsAllowed {
assert(conversionsEnabled);
_;
}
// allows execution by the BancorNetwork contract only
modifier bancorNetworkOnly {
IBancorNetwork bancorNetwork = IBancorNetwork(registry.getAddress(ContractIds.BANCOR_NETWORK));
require(msg.sender == address(bancorNetwork));
_;
}
/**
@dev returns the number of connector tokens defined
@return number of connector tokens
*/
function connectorTokenCount() public view returns (uint16) {
return uint16(connectorTokens.length);
}
/*
@dev allows the owner to update the registry contract address
@param _registry address of a bancor converter registry contract
*/
function setRegistry(IContractRegistry _registry)
public
ownerOnly
validAddress(_registry)
notThis(_registry)
{
registry = _registry;
}
/*
@dev allows the owner to update & enable the conversion whitelist contract address
when set, only addresses that are whitelisted are actually allowed to use the converter
note that the whitelist check is actually done by the BancorNetwork contract
@param _whitelist address of a whitelist contract
*/
function setConversionWhitelist(IWhitelist _whitelist)
public
ownerOnly
notThis(_whitelist)
{
conversionWhitelist = _whitelist;
}
/*
@dev allows the manager to update the quick buy path
@param _path new quick buy path, see conversion path format in the bancorNetwork contract
*/
function setQuickBuyPath(IERC20Token[] _path)
public
ownerOnly
validConversionPath(_path)
{
quickBuyPath = _path;
}
/*
@dev allows the manager to clear the quick buy path
*/
function clearQuickBuyPath() public ownerOnly {
quickBuyPath.length = 0;
}
/**
@dev returns the length of the quick buy path array
@return quick buy path length
*/
function getQuickBuyPathLength() public view returns (uint256) {
return quickBuyPath.length;
}
/**
@dev disables the entire conversion functionality
this is a safety mechanism in case of a emergency
can only be called by the manager
@param _disable true to disable conversions, false to re-enable them
*/
function disableConversions(bool _disable) public ownerOrManagerOnly {
conversionsEnabled = !_disable;
}
/**
@dev updates the current conversion fee
can only be called by the manager
@param _conversionFee new conversion fee, represented in ppm
*/
function setConversionFee(uint32 _conversionFee)
public
ownerOrManagerOnly
validConversionFee(_conversionFee)
{
emit ConversionFeeUpdate(conversionFee, _conversionFee);
conversionFee = _conversionFee;
}
/*
@dev given a return amount, returns the amount minus the conversion fee
@param _amount return amount
@param _magnitude 1 for standard conversion, 2 for cross connector conversion
@return return amount minus conversion fee
*/
function getFinalAmount(uint256 _amount, uint8 _magnitude) public view returns (uint256) {
return safeMul(_amount, (MAX_CONVERSION_FEE - conversionFee) ** _magnitude) / MAX_CONVERSION_FEE ** _magnitude;
}
/**
@dev defines a new connector for the token
can only be called by the owner while the converter is inactive
@param _token address of the connector token
@param _weight constant connector weight, represented in ppm, 1-1000000
@param _enableVirtualBalance true to enable virtual balance for the connector, false to disable it
*/
function addConnector(IERC20Token _token, uint32 _weight, bool _enableVirtualBalance)
public
ownerOnly
inactive
validAddress(_token)
notThis(_token)
validConnectorWeight(_weight)
{
require(_token != token && !connectors[_token].isSet && totalConnectorWeight + _weight <= MAX_WEIGHT); // validate input
connectors[_token].virtualBalance = 0;
connectors[_token].weight = _weight;
connectors[_token].isVirtualBalanceEnabled = _enableVirtualBalance;
connectors[_token].isPurchaseEnabled = true;
connectors[_token].isSet = true;
connectorTokens.push(_token);
totalConnectorWeight += _weight;
}
/**
@dev updates one of the token connectors
can only be called by the owner
@param _connectorToken address of the connector token
@param _weight constant connector weight, represented in ppm, 1-1000000
@param _enableVirtualBalance true to enable virtual balance for the connector, false to disable it
@param _virtualBalance new connector's virtual balance
*/
function updateConnector(IERC20Token _connectorToken, uint32 _weight, bool _enableVirtualBalance, uint256 _virtualBalance)
public
ownerOnly
validConnector(_connectorToken)
validConnectorWeight(_weight)
{
Connector storage connector = connectors[_connectorToken];
require(totalConnectorWeight - connector.weight + _weight <= MAX_WEIGHT); // validate input
totalConnectorWeight = totalConnectorWeight - connector.weight + _weight;
connector.weight = _weight;
connector.isVirtualBalanceEnabled = _enableVirtualBalance;
connector.virtualBalance = _virtualBalance;
}
/**
@dev disables purchasing with the given connector token in case the connector token got compromised
can only be called by the owner
note that selling is still enabled regardless of this flag and it cannot be disabled by the owner
@param _connectorToken connector token contract address
@param _disable true to disable the token, false to re-enable it
*/
function disableConnectorPurchases(IERC20Token _connectorToken, bool _disable)
public
ownerOnly
validConnector(_connectorToken)
{
connectors[_connectorToken].isPurchaseEnabled = !_disable;
}
/**
@dev returns the connector's virtual balance if one is defined, otherwise returns the actual balance
@param _connectorToken connector token contract address
@return connector balance
*/
function getConnectorBalance(IERC20Token _connectorToken)
public
view
validConnector(_connectorToken)
returns (uint256)
{
Connector storage connector = connectors[_connectorToken];
return connector.isVirtualBalanceEnabled ? connector.virtualBalance : _connectorToken.balanceOf(this);
}
/**
@dev returns the expected return for converting a specific amount of _fromToken to _toToken
@param _fromToken ERC20 token to convert from
@param _toToken ERC20 token to convert to
@param _amount amount to convert, in fromToken
@return expected conversion return amount
*/
function getReturn(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount) public view returns (uint256) {
require(_fromToken != _toToken); // validate input
// conversion between the token and one of its connectors
if (_toToken == token)
return getPurchaseReturn(_fromToken, _amount);
else if (_fromToken == token)
return getSaleReturn(_toToken, _amount);
// conversion between 2 connectors
return getCrossConnectorReturn(_fromToken, _toToken, _amount);
}
/**
@dev returns the expected return for buying the token for a connector token
@param _connectorToken connector token contract address
@param _depositAmount amount to deposit (in the connector token)
@return expected purchase return amount
*/
function getPurchaseReturn(IERC20Token _connectorToken, uint256 _depositAmount)
public
view
active
validConnector(_connectorToken)
returns (uint256)
{
Connector storage connector = connectors[_connectorToken];
require(connector.isPurchaseEnabled); // validate input
uint256 tokenSupply = token.totalSupply();
uint256 connectorBalance = getConnectorBalance(_connectorToken);
IBancorFormula formula = IBancorFormula(registry.getAddress(ContractIds.BANCOR_FORMULA));
uint256 amount = formula.calculatePurchaseReturn(tokenSupply, connectorBalance, connector.weight, _depositAmount);
// return the amount minus the conversion fee
return getFinalAmount(amount, 1);
}
/**
@dev returns the expected return for selling the token for one of its connector tokens
@param _connectorToken connector token contract address
@param _sellAmount amount to sell (in the smart token)
@return expected sale return amount
*/
function getSaleReturn(IERC20Token _connectorToken, uint256 _sellAmount)
public
view
active
validConnector(_connectorToken)
returns (uint256)
{
Connector storage connector = connectors[_connectorToken];
uint256 tokenSupply = token.totalSupply();
uint256 connectorBalance = getConnectorBalance(_connectorToken);
IBancorFormula formula = IBancorFormula(registry.getAddress(ContractIds.BANCOR_FORMULA));
uint256 amount = formula.calculateSaleReturn(tokenSupply, connectorBalance, connector.weight, _sellAmount);
// return the amount minus the conversion fee
return getFinalAmount(amount, 1);
}
/**
@dev returns the expected return for selling one of the connector tokens for another connector token
@param _fromConnectorToken contract address of the connector token to convert from
@param _toConnectorToken contract address of the connector token to convert to
@param _sellAmount amount to sell (in the from connector token)
@return expected sale return amount (in the to connector token)
*/
function getCrossConnectorReturn(IERC20Token _fromConnectorToken, IERC20Token _toConnectorToken, uint256 _sellAmount)
public
view
active
validConnector(_fromConnectorToken)
validConnector(_toConnectorToken)
returns (uint256)
{
Connector storage fromConnector = connectors[_fromConnectorToken];
Connector storage toConnector = connectors[_toConnectorToken];
require(toConnector.isPurchaseEnabled); // validate input
uint256 fromConnectorBalance = getConnectorBalance(_fromConnectorToken);
uint256 toConnectorBalance = getConnectorBalance(_toConnectorToken);
IBancorFormula formula = IBancorFormula(registry.getAddress(ContractIds.BANCOR_FORMULA));
uint256 amount = formula.calculateCrossConnectorReturn(fromConnectorBalance, fromConnector.weight, toConnectorBalance, toConnector.weight, _sellAmount);
// return the amount minus the conversion fee
// the fee is higher (magnitude = 2) since cross connector conversion equals 2 conversions (from / to the smart token)
return getFinalAmount(amount, 2);
}
/**
@dev converts a specific amount of _fromToken to _toToken
@param _fromToken ERC20 token to convert from
@param _toToken ERC20 token to convert to
@param _amount amount to convert, in fromToken
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return conversion return amount
*/
function convertInternal(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn)
public
bancorNetworkOnly
conversionsAllowed
greaterThanZero(_minReturn)
returns (uint256)
{
require(_fromToken != _toToken); // validate input
// conversion between the token and one of its connectors
if (_toToken == token)
return buy(_fromToken, _amount, _minReturn);
else if (_fromToken == token)
return sell(_toToken, _amount, _minReturn);
// conversion between 2 connectors
uint256 amount = getCrossConnectorReturn(_fromToken, _toToken, _amount);
// ensure the trade gives something in return and meets the minimum requested amount
require(amount != 0 && amount >= _minReturn);
// update the source token virtual balance if relevant
Connector storage fromConnector = connectors[_fromToken];
if (fromConnector.isVirtualBalanceEnabled)
fromConnector.virtualBalance = safeAdd(fromConnector.virtualBalance, _amount);
// update the target token virtual balance if relevant
Connector storage toConnector = connectors[_toToken];
if (toConnector.isVirtualBalanceEnabled)
toConnector.virtualBalance = safeSub(toConnector.virtualBalance, amount);
// ensure that the trade won't deplete the connector balance
uint256 toConnectorBalance = getConnectorBalance(_toToken);
assert(amount < toConnectorBalance);
// transfer funds from the caller in the from connector token
assert(_fromToken.transferFrom(msg.sender, this, _amount));
// transfer funds to the caller in the to connector token
// the transfer might fail if the actual connector balance is smaller than the virtual balance
assert(_toToken.transfer(msg.sender, amount));
// calculate conversion fee and dispatch the conversion event
// the fee is higher (magnitude = 2) since cross connector conversion equals 2 conversions (from / to the smart token)
uint256 feeAmount = safeSub(amount, getFinalAmount(amount, 2));
dispatchConversionEvent(_fromToken, _toToken, _amount, amount, feeAmount);
// dispatch price data updates for the smart token / both connectors
emit PriceDataUpdate(_fromToken, token.totalSupply(), getConnectorBalance(_fromToken), fromConnector.weight);
emit PriceDataUpdate(_toToken, token.totalSupply(), getConnectorBalance(_toToken), toConnector.weight);
return amount;
}
/**
@dev converts a specific amount of _fromToken to _toToken
@param _fromToken ERC20 token to convert from
@param _toToken ERC20 token to convert to
@param _amount amount to convert, in fromToken
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return conversion return amount
*/
function convert(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256) {
convertPath = [_fromToken, token, _toToken];
return quickConvert(convertPath, _amount, _minReturn);
}
/**
@dev buys the token by depositing one of its connector tokens
@param _connectorToken connector token contract address
@param _depositAmount amount to deposit (in the connector token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return buy return amount
*/
function buy(IERC20Token _connectorToken, uint256 _depositAmount, uint256 _minReturn) internal returns (uint256) {
uint256 amount = getPurchaseReturn(_connectorToken, _depositAmount);
// ensure the trade gives something in return and meets the minimum requested amount
require(amount != 0 && amount >= _minReturn);
// update virtual balance if relevant
Connector storage connector = connectors[_connectorToken];
if (connector.isVirtualBalanceEnabled)
connector.virtualBalance = safeAdd(connector.virtualBalance, _depositAmount);
// transfer funds from the caller in the connector token
assert(_connectorToken.transferFrom(msg.sender, this, _depositAmount));
// issue new funds to the caller in the smart token
token.issue(msg.sender, amount);
// calculate conversion fee and dispatch the conversion event
uint256 feeAmount = safeSub(amount, getFinalAmount(amount, 1));
dispatchConversionEvent(_connectorToken, token, _depositAmount, amount, feeAmount);
// dispatch price data update for the smart token/connector
emit PriceDataUpdate(_connectorToken, token.totalSupply(), getConnectorBalance(_connectorToken), connector.weight);
return amount;
}
/**
@dev sells the token by withdrawing from one of its connector tokens
@param _connectorToken connector token contract address
@param _sellAmount amount to sell (in the smart token)
@param _minReturn if the conversion results in an amount smaller the minimum return - it is cancelled, must be nonzero
@return sell return amount
*/
function sell(IERC20Token _connectorToken, uint256 _sellAmount, uint256 _minReturn) internal returns (uint256) {
require(_sellAmount <= token.balanceOf(msg.sender)); // validate input
uint256 amount = getSaleReturn(_connectorToken, _sellAmount);
// ensure the trade gives something in return and meets the minimum requested amount
require(amount != 0 && amount >= _minReturn);
// ensure that the trade will only deplete the connector balance if the total supply is depleted as well
uint256 tokenSupply = token.totalSupply();
uint256 connectorBalance = getConnectorBalance(_connectorToken);
assert(amount < connectorBalance || (amount == connectorBalance && _sellAmount == tokenSupply));
// update virtual balance if relevant
Connector storage connector = connectors[_connectorToken];
if (connector.isVirtualBalanceEnabled)
connector.virtualBalance = safeSub(connector.virtualBalance, amount);
// destroy _sellAmount from the caller's balance in the smart token
token.destroy(msg.sender, _sellAmount);
// transfer funds to the caller in the connector token
// the transfer might fail if the actual connector balance is smaller than the virtual balance
assert(_connectorToken.transfer(msg.sender, amount));
// calculate conversion fee and dispatch the conversion event
uint256 feeAmount = safeSub(amount, getFinalAmount(amount, 1));
dispatchConversionEvent(token, _connectorToken, _sellAmount, amount, feeAmount);
// dispatch price data update for the smart token/connector
emit PriceDataUpdate(_connectorToken, token.totalSupply(), getConnectorBalance(_connectorToken), connector.weight);
return amount;
}
/**
@dev converts the token to any other token in the bancor network by following a predefined conversion path
note that when converting from an ERC20 token (as opposed to a smart token), allowance must be set beforehand
@param _path conversion path, see conversion path format in the BancorNetwork contract
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@return tokens issued in return
*/
function quickConvert(IERC20Token[] _path, uint256 _amount, uint256 _minReturn)
public
payable
validConversionPath(_path)
returns (uint256)
{
return quickConvertPrioritized(_path, _amount, _minReturn, 0x0, 0x0, 0x0, 0x0);
}
/**
@dev converts the token to any other token in the bancor network by following a predefined conversion path
note that when converting from an ERC20 token (as opposed to a smart token), allowance must be set beforehand
@param _path conversion path, see conversion path format in the BancorNetwork contract
@param _amount amount to convert from (in the initial source token)
@param _minReturn if the conversion results in an amount smaller than the minimum return - it is cancelled, must be nonzero
@param _block if the current block exceeded the given parameter - it is cancelled
@param _v (signature[128:130]) associated with the signer address and helps validating if the signature is legit
@param _r (signature[0:64]) associated with the signer address and helps validating if the signature is legit
@param _s (signature[64:128]) associated with the signer address and helps validating if the signature is legit
@return tokens issued in return
*/
function quickConvertPrioritized(IERC20Token[] _path, uint256 _amount, uint256 _minReturn, uint256 _block, uint8 _v, bytes32 _r, bytes32 _s)
public
payable
validConversionPath(_path)
returns (uint256)
{
IERC20Token fromToken = _path[0];
IBancorNetwork bancorNetwork = IBancorNetwork(registry.getAddress(ContractIds.BANCOR_NETWORK));
// we need to transfer the source tokens from the caller to the BancorNetwork contract,
// so it can execute the conversion on behalf of the caller
if (msg.value == 0) {
// not ETH, send the source tokens to the BancorNetwork contract
// if the token is the smart token, no allowance is required - destroy the tokens
// from the caller and issue them to the BancorNetwork contract
if (fromToken == token) {
token.destroy(msg.sender, _amount); // destroy _amount tokens from the caller's balance in the smart token
token.issue(bancorNetwork, _amount); // issue _amount new tokens to the BancorNetwork contract
} else {
// otherwise, we assume we already have allowance, transfer the tokens directly to the BancorNetwork contract
assert(fromToken.transferFrom(msg.sender, bancorNetwork, _amount));
}
}
// execute the conversion and pass on the ETH with the call
return bancorNetwork.convertForPrioritized2.value(msg.value)(_path, _amount, _minReturn, msg.sender, _block, _v, _r, _s);
}
// deprecated, backward compatibility
function change(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _minReturn) public returns (uint256) {
return convertInternal(_fromToken, _toToken, _amount, _minReturn);
}
/**
@dev helper, dispatches the Conversion event
@param _fromToken ERC20 token to convert from
@param _toToken ERC20 token to convert to
@param _amount amount purchased/sold (in the source token)
@param _returnAmount amount returned (in the target token)
*/
function dispatchConversionEvent(IERC20Token _fromToken, IERC20Token _toToken, uint256 _amount, uint256 _returnAmount, uint256 _feeAmount) private {
// fee amount is converted to 255 bits -
// negative amount means the fee is taken from the source token, positive amount means its taken from the target token
// currently the fee is always taken from the target token
// since we convert it to a signed number, we first ensure that it's capped at 255 bits to prevent overflow
assert(_feeAmount <= 2 ** 255);
emit Conversion(_fromToken, _toToken, msg.sender, _amount, _returnAmount, int256(_feeAmount));
}
/**
@dev fallback, buys the smart token with ETH
note that the purchase will use the price at the time of the purchase
*/
function() payable public {
quickConvert(quickBuyPath, msg.value, 1);
}
}File 11 of 11: ElementToken
pragma solidity ^0.4.11;
/**
* @title ERC20Basic
* @dev Simpler version of ERC20 interface
* @dev see https://github.com/ethereum/EIPs/issues/179
*/
contract ERC20Basic {
uint256 public totalSupply;
function balanceOf(address who) public constant returns (uint256);
function transfer(address to, uint256 value) public returns (bool);
event Transfer(address indexed from, address indexed to, uint256 value);
}
/**
* @title Ownable
* @dev The Ownable contract has an owner address, and provides basic authorization control
* functions, this simplifies the implementation of "user permissions".
*/
contract Ownable {
address public owner;
event OwnershipTransferred(address indexed previousOwner, address indexed newOwner);
/**
* @dev The Ownable constructor sets the original `owner` of the contract to the sender
* account.
*/
function Ownable() {
owner = msg.sender;
}
/**
* @dev Throws if called by any account other than the owner.
*/
modifier onlyOwner() {
require(msg.sender == owner);
_;
}
/**
* @dev Allows the current owner to transfer control of the contract to a newOwner.
* @param newOwner The address to transfer ownership to.
*/
function transferOwnership(address newOwner) onlyOwner public {
require(newOwner != address(0));
OwnershipTransferred(owner, newOwner);
owner = newOwner;
}
}
/**
* @title SafeMath
* @dev Math operations with safety checks that throw on error
*/
library SafeMath {
function mul(uint256 a, uint256 b) internal constant returns (uint256) {
uint256 c = a * b;
assert(a == 0 || c / a == b);
return c;
}
function div(uint256 a, uint256 b) internal constant returns (uint256) {
// assert(b > 0); // Solidity automatically throws when dividing by 0
uint256 c = a / b;
// assert(a == b * c + a % b); // There is no case in which this doesn't hold
return c;
}
function sub(uint256 a, uint256 b) internal constant returns (uint256) {
assert(b <= a);
return a - b;
}
function add(uint256 a, uint256 b) internal constant returns (uint256) {
uint256 c = a + b;
assert(c >= a);
return c;
}
}
/**
* @title Basic token
* @dev Basic version of StandardToken, with no allowances.
*/
contract BasicToken is ERC20Basic {
using SafeMath for uint256;
mapping(address => uint256) balances;
/**
* @dev transfer token for a specified address
* @param _to The address to transfer to.
* @param _value The amount to be transferred.
*/
function transfer(address _to, uint256 _value) public returns (bool) {
require(_to != address(0));
// SafeMath.sub will throw if there is not enough balance.
balances[msg.sender] = balances[msg.sender].sub(_value);
balances[_to] = balances[_to].add(_value);
Transfer(msg.sender, _to, _value);
return true;
}
/**
* @dev Gets the balance of the specified address.
* @param _owner The address to query the the balance of.
* @return An uint256 representing the amount owned by the passed address.
*/
function balanceOf(address _owner) public constant returns (uint256 balance) {
return balances[_owner];
}
}
/**
* @title ERC20 interface
* @dev see https://github.com/ethereum/EIPs/issues/20
*/
contract ERC20 is ERC20Basic {
function allowance(address owner, address spender) public constant returns (uint256);
function transferFrom(address from, address to, uint256 value) public returns (bool);
function approve(address spender, uint256 value) public returns (bool);
event Approval(address indexed owner, address indexed spender, uint256 value);
}
/**
* @title Standard ERC20 token
*
* @dev Implementation of the basic standard token.
* @dev https://github.com/ethereum/EIPs/issues/20
* @dev Based on code by FirstBlood: https://github.com/Firstbloodio/token/blob/master/smart_contract/FirstBloodToken.sol
*/
contract StandardToken is ERC20, BasicToken {
mapping (address => mapping (address => uint256)) allowed;
/**
* @dev Transfer tokens from one address to another
* @param _from address The address which you want to send tokens from
* @param _to address The address which you want to transfer to
* @param _value uint256 the amount of tokens to be transferred
*/
function transferFrom(address _from, address _to, uint256 _value) public returns (bool) {
require(_to != address(0));
uint256 _allowance = allowed[_from][msg.sender];
// Check is not needed because sub(_allowance, _value) will already throw if this condition is not met
// require (_value <= _allowance);
balances[_from] = balances[_from].sub(_value);
balances[_to] = balances[_to].add(_value);
allowed[_from][msg.sender] = _allowance.sub(_value);
Transfer(_from, _to, _value);
return true;
}
/**
* @dev Approve the passed address to spend the specified amount of tokens on behalf of msg.sender.
*
* 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
* @param _spender The address which will spend the funds.
* @param _value The amount of tokens to be spent.
*/
function approve(address _spender, uint256 _value) public returns (bool) {
allowed[msg.sender][_spender] = _value;
Approval(msg.sender, _spender, _value);
return true;
}
/**
* @dev Function to check the amount of tokens that an owner allowed to a spender.
* @param _owner address The address which owns the funds.
* @param _spender address The address which will spend the funds.
* @return A uint256 specifying the amount of tokens still available for the spender.
*/
function allowance(address _owner, address _spender) public constant returns (uint256 remaining) {
return allowed[_owner][_spender];
}
/**
* approve should be called when allowed[_spender] == 0. To increment
* allowed value is better to use this function to avoid 2 calls (and wait until
* the first transaction is mined)
* From MonolithDAO Token.sol
*/
function increaseApproval (address _spender, uint _addedValue)
returns (bool success) {
allowed[msg.sender][_spender] = allowed[msg.sender][_spender].add(_addedValue);
Approval(msg.sender, _spender, allowed[msg.sender][_spender]);
return true;
}
function decreaseApproval (address _spender, uint _subtractedValue)
returns (bool success) {
uint oldValue = allowed[msg.sender][_spender];
if (_subtractedValue > oldValue) {
allowed[msg.sender][_spender] = 0;
} else {
allowed[msg.sender][_spender] = oldValue.sub(_subtractedValue);
}
Approval(msg.sender, _spender, allowed[msg.sender][_spender]);
return true;
}
}
/**
* @title Pausable
* @dev Base contract which allows children to implement an emergency stop mechanism.
*/
contract Pausable is Ownable {
event Pause();
event Unpause();
bool public paused = false;
/**
* @dev Modifier to make a function callable only when the contract is not paused.
*/
modifier whenNotPaused() {
require(!paused);
_;
}
/**
* @dev Modifier to make a function callable only when the contract is paused.
*/
modifier whenPaused() {
require(paused);
_;
}
/**
* @dev called by the owner to pause, triggers stopped state
*/
function pause() onlyOwner whenNotPaused public {
paused = true;
Pause();
}
/**
* @dev called by the owner to unpause, returns to normal state
*/
function unpause() onlyOwner whenPaused public {
paused = false;
Unpause();
}
}
/**
* @title Element Token
* @dev ERC20 Element Token)
*
* All initial tokens are assigned to the creator of
* this contract.
*
*/
contract ElementToken is StandardToken, Pausable {
string public name = ''; // Set the token name for display
string public symbol = ''; // Set the token symbol for display
uint8 public decimals = 0; // Set the token symbol for display
/**
* @dev Don't allow tokens to be sent to the contract
*/
modifier rejectTokensToContract(address _to) {
require(_to != address(this));
_;
}
/**
* @dev ElementToken Constructor
* Runs only on initial contract creation.
*/
function ElementToken(string _name, string _symbol, uint256 _tokens, uint8 _decimals) {
name = _name;
symbol = _symbol;
decimals = _decimals;
totalSupply = _tokens * 10**uint256(decimals); // Set the total supply
balances[msg.sender] = totalSupply; // Creator address is assigned all
Transfer(0x0, msg.sender, totalSupply); // create Transfer event for minting
}
/**
* @dev Transfer token for a specified address when not paused
* @param _to The address to transfer to.
* @param _value The amount to be transferred.
*/
function transfer(address _to, uint256 _value) rejectTokensToContract(_to) public whenNotPaused returns (bool) {
return super.transfer(_to, _value);
}
/**
* @dev Transfer tokens from one address to another when not paused
* @param _from address The address which you want to send tokens from
* @param _to address The address which you want to transfer to
* @param _value uint256 the amount of tokens to be transferred
*/
function transferFrom(address _from, address _to, uint256 _value) rejectTokensToContract(_to) public whenNotPaused returns (bool) {
return super.transferFrom(_from, _to, _value);
}
/**
* @dev Aprove the passed address to spend the specified amount of tokens on behalf of msg.sender when not paused.
* @param _spender The address which will spend the funds.
* @param _value The amount of tokens to be spent.
*/
function approve(address _spender, uint256 _value) public whenNotPaused returns (bool) {
return super.approve(_spender, _value);
}
/**
* Adding whenNotPaused
*/
function increaseApproval (address _spender, uint _addedValue) public whenNotPaused returns (bool success) {
return super.increaseApproval(_spender, _addedValue);
}
/**
* Adding whenNotPaused
*/
function decreaseApproval (address _spender, uint _subtractedValue) public whenNotPaused returns (bool success) {
return super.decreaseApproval(_spender, _subtractedValue);
}
}