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SwapUtils.sol
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SwapUtils.sol
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// SPDX-License-Identifier: MIT
pragma solidity 0.6.12;
import "@openzeppelin/contracts/math/SafeMath.sol";
import "@openzeppelin/contracts/token/ERC20/SafeERC20.sol";
import "./LPToken.sol";
import "./MathUtils.sol";
/**
* @title SwapUtils library
* @notice A library to be used within Swap.sol. Contains functions responsible for custody and AMM functionalities.
* @dev Contracts relying on this library must initialize SwapUtils.Swap struct then use this library
* for SwapUtils.Swap struct. Note that this library contains both functions called by users and admins.
* Admin functions should be protected within contracts using this library.
*/
library SwapUtils {
using SafeERC20 for IERC20;
using SafeMath for uint256;
using MathUtils for uint256;
/*** EVENTS ***/
event TokenSwap(
address indexed buyer,
uint256 tokensSold,
uint256 tokensBought,
uint128 soldId,
uint128 boughtId
);
event AddLiquidity(
address indexed provider,
uint256[] tokenAmounts,
uint256[] fees,
uint256 invariant,
uint256 lpTokenSupply
);
event RemoveLiquidity(
address indexed provider,
uint256[] tokenAmounts,
uint256 lpTokenSupply
);
event RemoveLiquidityOne(
address indexed provider,
uint256 lpTokenAmount,
uint256 lpTokenSupply,
uint256 boughtId,
uint256 tokensBought
);
event RemoveLiquidityImbalance(
address indexed provider,
uint256[] tokenAmounts,
uint256[] fees,
uint256 invariant,
uint256 lpTokenSupply
);
event NewAdminFee(uint256 newAdminFee);
event NewSwapFee(uint256 newSwapFee);
event NewWithdrawFee(uint256 newWithdrawFee);
event NewDepositFee(uint256 newDepositFee);
event RampA(
uint256 oldA,
uint256 newA,
uint256 initialTime,
uint256 futureTime
);
event StopRampA(uint256 currentA, uint256 time);
struct Swap {
// variables around the ramp management of A,
// the amplification coefficient * n * (n - 1)
// see https://www.curve.fi/stableswap-paper.pdf for details
uint256 initialA;
uint256 futureA;
uint256 initialATime;
uint256 futureATime;
// fee calculation
uint256 swapFee;
uint256 adminFee;
uint256 defaultDepositFee;
uint256 defaultWithdrawFee;
address devaddr;
LPToken lpToken;
// contract references for all tokens being pooled
IERC20[] pooledTokens;
// multipliers for each pooled token's precision to get to POOL_PRECISION_DECIMALS
// for example, TBTC has 18 decimals, so the multiplier should be 1. WBTC
// has 8, so the multiplier should be 10 ** 18 / 10 ** 8 => 10 ** 10
uint256[] tokenPrecisionMultipliers;
// the pool balance of each token, in the token's precision
// the contract's actual token balance might differ
uint256[] balances;
mapping(address => uint256) depositTimestamp;
mapping(address => uint256) withdrawFeeMultiplier;
}
// Struct storing variables used in calculations in the
// calculateWithdrawOneTokenDY function to avoid stack too deep errors
struct CalculateWithdrawOneTokenDYInfo {
uint256 d0;
uint256 d1;
uint256 newY;
uint256 feePerToken;
uint256 preciseA;
}
// Struct storing variables used in calculation in addLiquidity function
// to avoid stack too deep error
struct AddLiquidityInfo {
uint256 d0;
uint256 d1;
uint256 d2;
uint256 preciseA;
}
// Struct storing variables used in calculation in removeLiquidityImbalance function
// to avoid stack too deep error
struct RemoveLiquidityImbalanceInfo {
uint256 d0;
uint256 d1;
uint256 d2;
uint256 preciseA;
}
// the precision all pools tokens will be converted to
uint8 public constant POOL_PRECISION_DECIMALS = 18;
// the denominator used to calculate admin and LP fees. For example, an
// LP fee might be something like tradeAmount.mul(fee).div(FEE_DENOMINATOR)
uint256 private constant FEE_DENOMINATOR = 10**10;
// Max swap fee is 1% or 100bps of each swap
uint256 public constant MAX_SWAP_FEE = 10**8;
// Max adminFee is 100% of the swapFee
// adminFee does not add additional fee on top of swapFee
// Instead it takes a certain % of the swapFee. Therefore it has no impact on the
// users but only on the earnings of LPs
uint256 public constant MAX_ADMIN_FEE = 10**10;
// Max withdrawFee is 1% of the value withdrawn
// Fee will be redistributed to the LPs in the pool, rewarding
// long term providers.
uint256 public constant MAX_WITHDRAW_FEE = 10**8;
// Max depositFee is 1% of the value deposited
uint256 public constant MAX_DEPOSIT_FEE = 10**8;
// Constant value used as max loop limit
uint256 private constant MAX_LOOP_LIMIT = 256;
// Constant values used in ramping A calculations
uint256 public constant A_PRECISION = 100;
uint256 public constant MAX_A = 10**6;
uint256 private constant MAX_A_CHANGE = 2;
uint256 private constant MIN_RAMP_TIME = 14 days;
/*** VIEW & PURE FUNCTIONS ***/
/**
* @notice Return A, the amplification coefficient * n * (n - 1)
* @dev See the StableSwap paper for details
* @param self Swap struct to read from
* @return A parameter
*/
function getA(Swap storage self) external view returns (uint256) {
return _getA(self);
}
/**
* @notice Return A, the amplification coefficient * n * (n - 1)
* @dev See the StableSwap paper for details
* @param self Swap struct to read from
* @return A parameter
*/
function _getA(Swap storage self) internal view returns (uint256) {
return _getAPrecise(self).div(A_PRECISION);
}
/**
* @notice Return A in its raw precision
* @dev See the StableSwap paper for details
* @param self Swap struct to read from
* @return A parameter in its raw precision form
*/
function getAPrecise(Swap storage self) external view returns (uint256) {
return _getAPrecise(self);
}
/**
* @notice Calculates and returns A based on the ramp settings
* @dev See the StableSwap paper for details
* @param self Swap struct to read from
* @return A parameter in its raw precision form
*/
function _getAPrecise(Swap storage self) internal view returns (uint256) {
uint256 t1 = self.futureATime; // time when ramp is finished
uint256 a1 = self.futureA; // final A value when ramp is finished
if (block.timestamp < t1) {
uint256 t0 = self.initialATime; // time when ramp is started
uint256 a0 = self.initialA; // initial A value when ramp is started
if (a1 > a0) {
// a0 + (a1 - a0) * (block.timestamp - t0) / (t1 - t0)
return
a0.add(
a1.sub(a0).mul(block.timestamp.sub(t0)).div(t1.sub(t0))
);
} else {
// a0 - (a0 - a1) * (block.timestamp - t0) / (t1 - t0)
return
a0.sub(
a0.sub(a1).mul(block.timestamp.sub(t0)).div(t1.sub(t0))
);
}
} else {
return a1;
}
}
/**
* @notice Retrieves the timestamp of last deposit made by the given address
* @param self Swap struct to read from
* @return timestamp of last deposit
*/
function getDepositTimestamp(Swap storage self, address user)
external
view
returns (uint256)
{
return self.depositTimestamp[user];
}
/**
* @notice Calculate the dy, the amount of selected token that user receives and
* the fee of withdrawing in one token
* @param account the address that is withdrawing
* @param tokenAmount the amount to withdraw in the pool's precision
* @param tokenIndex which token will be withdrawn
* @param self Swap struct to read from
* @return the amount of token user will receive and the associated swap fee
*/
function calculateWithdrawOneToken(
Swap storage self,
address account,
uint256 tokenAmount,
uint8 tokenIndex
) public view returns (uint256, uint256) {
uint256 dy;
uint256 newY;
(dy, newY) = calculateWithdrawOneTokenDY(self, tokenIndex, tokenAmount);
// dy_0 (without fees)
// dy, dy_0 - dy
uint256 dySwapFee =
_xp(self)[tokenIndex]
.sub(newY)
.div(self.tokenPrecisionMultipliers[tokenIndex])
.sub(dy);
dy = dy
.mul(
FEE_DENOMINATOR.sub(calculateCurrentWithdrawFee(self, account))
)
.div(FEE_DENOMINATOR);
return (dy, dySwapFee);
}
/**
* @notice Calculate the dy of withdrawing in one token
* @param self Swap struct to read from
* @param tokenIndex which token will be withdrawn
* @param tokenAmount the amount to withdraw in the pools precision
* @return the d and the new y after withdrawing one token
*/
function calculateWithdrawOneTokenDY(
Swap storage self,
uint8 tokenIndex,
uint256 tokenAmount
) internal view returns (uint256, uint256) {
require(
tokenIndex < self.pooledTokens.length,
"Token index out of range"
);
// Get the current D, then solve the stableswap invariant
// y_i for D - tokenAmount
uint256[] memory xp = _xp(self);
CalculateWithdrawOneTokenDYInfo memory v =
CalculateWithdrawOneTokenDYInfo(0, 0, 0, 0, 0);
v.preciseA = _getAPrecise(self);
v.d0 = getD(xp, v.preciseA);
v.d1 = v.d0.sub(tokenAmount.mul(v.d0).div(self.lpToken.totalSupply()));
require(tokenAmount <= xp[tokenIndex], "Withdraw exceeds available");
v.newY = getYD(v.preciseA, tokenIndex, xp, v.d1);
uint256[] memory xpReduced = new uint256[](xp.length);
v.feePerToken = _feePerToken(self);
for (uint256 i = 0; i < self.pooledTokens.length; i++) {
uint256 xpi = xp[i];
// if i == tokenIndex, dxExpected = xp[i] * d1 / d0 - newY
// else dxExpected = xp[i] - (xp[i] * d1 / d0)
// xpReduced[i] -= dxExpected * fee / FEE_DENOMINATOR
xpReduced[i] = xpi.sub(
(
(i == tokenIndex)
? xpi.mul(v.d1).div(v.d0).sub(v.newY)
: xpi.sub(xpi.mul(v.d1).div(v.d0))
)
.mul(v.feePerToken)
.div(FEE_DENOMINATOR)
);
}
uint256 dy =
xpReduced[tokenIndex].sub(
getYD(v.preciseA, tokenIndex, xpReduced, v.d1)
);
dy = dy.sub(1).div(self.tokenPrecisionMultipliers[tokenIndex]);
return (dy, v.newY);
}
/**
* @notice Calculate the price of a token in the pool with given
* precision-adjusted balances and a particular D.
*
* @dev This is accomplished via solving the invariant iteratively.
* See the StableSwap paper and Curve.fi implementation for further details.
*
* x_1**2 + x1 * (sum' - (A*n**n - 1) * D / (A * n**n)) = D ** (n + 1) / (n ** (2 * n) * prod' * A)
* x_1**2 + b*x_1 = c
* x_1 = (x_1**2 + c) / (2*x_1 + b)
*
* @param a the amplification coefficient * n * (n - 1). See the StableSwap paper for details.
* @param tokenIndex Index of token we are calculating for.
* @param xp a precision-adjusted set of pool balances. Array should be
* the same cardinality as the pool.
* @param d the stableswap invariant
* @return the price of the token, in the same precision as in xp
*/
function getYD(
uint256 a,
uint8 tokenIndex,
uint256[] memory xp,
uint256 d
) internal pure returns (uint256) {
uint256 numTokens = xp.length;
require(tokenIndex < numTokens, "Token not found");
uint256 c = d;
uint256 s;
uint256 nA = a.mul(numTokens);
for (uint256 i = 0; i < numTokens; i++) {
if (i != tokenIndex) {
s = s.add(xp[i]);
c = c.mul(d).div(xp[i].mul(numTokens));
// If we were to protect the division loss we would have to keep the denominator separate
// and divide at the end. However this leads to overflow with large numTokens or/and D.
// c = c * D * D * D * ... overflow!
}
}
c = c.mul(d).mul(A_PRECISION).div(nA.mul(numTokens));
uint256 b = s.add(d.mul(A_PRECISION).div(nA));
uint256 yPrev;
uint256 y = d;
for (uint256 i = 0; i < MAX_LOOP_LIMIT; i++) {
yPrev = y;
y = y.mul(y).add(c).div(y.mul(2).add(b).sub(d));
if (y.within1(yPrev)) {
return y;
}
}
revert("Approximation did not converge");
}
/**
* @notice Get D, the StableSwap invariant, based on a set of balances and a particular A.
* @param xp a precision-adjusted set of pool balances. Array should be the same cardinality
* as the pool.
* @param a the amplification coefficient * n * (n - 1) in A_PRECISION.
* See the StableSwap paper for details
* @return the invariant, at the precision of the pool
*/
function getD(uint256[] memory xp, uint256 a)
internal
pure
returns (uint256)
{
uint256 numTokens = xp.length;
uint256 s;
for (uint256 i = 0; i < numTokens; i++) {
s = s.add(xp[i]);
}
if (s == 0) {
return 0;
}
uint256 prevD;
uint256 d = s;
uint256 nA = a.mul(numTokens);
for (uint256 i = 0; i < MAX_LOOP_LIMIT; i++) {
uint256 dP = d;
for (uint256 j = 0; j < numTokens; j++) {
dP = dP.mul(d).div(xp[j].mul(numTokens));
// If we were to protect the division loss we would have to keep the denominator separate
// and divide at the end. However this leads to overflow with large numTokens or/and D.
// dP = dP * D * D * D * ... overflow!
}
prevD = d;
d = nA.mul(s).div(A_PRECISION).add(dP.mul(numTokens)).mul(d).div(
nA.sub(A_PRECISION).mul(d).div(A_PRECISION).add(
numTokens.add(1).mul(dP)
)
);
if (d.within1(prevD)) {
return d;
}
}
// Convergence should occur in 4 loops or less. If this is reached, there may be something wrong
// with the pool. If this were to occur repeatedly, LPs should withdraw via `removeLiquidity()`
// function which does not rely on D.
revert("D does not converge");
}
/**
* @notice Get D, the StableSwap invariant, based on self Swap struct
* @param self Swap struct to read from
* @return The invariant, at the precision of the pool
*/
function getD(Swap storage self) internal view returns (uint256) {
return getD(_xp(self), _getAPrecise(self));
}
/**
* @notice Given a set of balances and precision multipliers, return the
* precision-adjusted balances.
*
* @param balances an array of token balances, in their native precisions.
* These should generally correspond with pooled tokens.
*
* @param precisionMultipliers an array of multipliers, corresponding to
* the amounts in the balances array. When multiplied together they
* should yield amounts at the pool's precision.
*
* @return an array of amounts "scaled" to the pool's precision
*/
function _xp(
uint256[] memory balances,
uint256[] memory precisionMultipliers
) internal pure returns (uint256[] memory) {
uint256 numTokens = balances.length;
require(
numTokens == precisionMultipliers.length,
"Balances must match multipliers"
);
uint256[] memory xp = new uint256[](numTokens);
for (uint256 i = 0; i < numTokens; i++) {
xp[i] = balances[i].mul(precisionMultipliers[i]);
}
return xp;
}
/**
* @notice Return the precision-adjusted balances of all tokens in the pool
* @param self Swap struct to read from
* @param balances array of balances to scale
* @return balances array "scaled" to the pool's precision, allowing
* them to be more easily compared.
*/
function _xp(Swap storage self, uint256[] memory balances)
internal
view
returns (uint256[] memory)
{
return _xp(balances, self.tokenPrecisionMultipliers);
}
/**
* @notice Return the precision-adjusted balances of all tokens in the pool
* @param self Swap struct to read from
* @return the pool balances "scaled" to the pool's precision, allowing
* them to be more easily compared.
*/
function _xp(Swap storage self) internal view returns (uint256[] memory) {
return _xp(self.balances, self.tokenPrecisionMultipliers);
}
/**
* @notice Get the virtual price, to help calculate profit
* @param self Swap struct to read from
* @return the virtual price, scaled to precision of POOL_PRECISION_DECIMALS
*/
function getVirtualPrice(Swap storage self)
external
view
returns (uint256)
{
uint256 d = getD(_xp(self), _getAPrecise(self));
uint256 supply = self.lpToken.totalSupply();
if (supply > 0) {
return
d.mul(10**uint256(ERC20(self.lpToken).decimals())).div(supply);
}
return 0;
}
/**
* @notice Calculate the new balances of the tokens given the indexes of the token
* that is swapped from (FROM) and the token that is swapped to (TO).
* This function is used as a helper function to calculate how much TO token
* the user should receive on swap.
*
* @param self Swap struct to read from
* @param tokenIndexFrom index of FROM token
* @param tokenIndexTo index of TO token
* @param x the new total amount of FROM token
* @param xp balances of the tokens in the pool
* @return the amount of TO token that should remain in the pool
*/
function getY(
Swap storage self,
uint8 tokenIndexFrom,
uint8 tokenIndexTo,
uint256 x,
uint256[] memory xp
) internal view returns (uint256) {
uint256 numTokens = self.pooledTokens.length;
require(
tokenIndexFrom != tokenIndexTo,
"Can't compare token to itself"
);
require(
tokenIndexFrom < numTokens && tokenIndexTo < numTokens,
"Tokens must be in pool"
);
uint256 a = _getAPrecise(self);
uint256 d = getD(xp, a);
uint256 c = d;
uint256 s;
uint256 nA = numTokens.mul(a);
uint256 _x;
for (uint256 i = 0; i < numTokens; i++) {
if (i == tokenIndexFrom) {
_x = x;
} else if (i != tokenIndexTo) {
_x = xp[i];
} else {
continue;
}
s = s.add(_x);
c = c.mul(d).div(_x.mul(numTokens));
// If we were to protect the division loss we would have to keep the denominator separate
// and divide at the end. However this leads to overflow with large numTokens or/and D.
// c = c * D * D * D * ... overflow!
}
c = c.mul(d).mul(A_PRECISION).div(nA.mul(numTokens));
uint256 b = s.add(d.mul(A_PRECISION).div(nA));
uint256 yPrev;
uint256 y = d;
// iterative approximation
for (uint256 i = 0; i < MAX_LOOP_LIMIT; i++) {
yPrev = y;
y = y.mul(y).add(c).div(y.mul(2).add(b).sub(d));
if (y.within1(yPrev)) {
return y;
}
}
revert("Approximation did not converge");
}
/**
* @notice Externally calculates a swap between two tokens.
* @param self Swap struct to read from
* @param tokenIndexFrom the token to sell
* @param tokenIndexTo the token to buy
* @param dx the number of tokens to sell. If the token charges a fee on transfers,
* use the amount that gets transferred after the fee.
* @return dy the number of tokens the user will get
*/
function calculateSwap(
Swap storage self,
uint8 tokenIndexFrom,
uint8 tokenIndexTo,
uint256 dx
) external view returns (uint256 dy) {
(dy, ) = _calculateSwap(self, tokenIndexFrom, tokenIndexTo, dx);
}
/**
* @notice Internally calculates a swap between two tokens.
*
* @dev The caller is expected to transfer the actual amounts (dx and dy)
* using the token contracts.
*
* @param self Swap struct to read from
* @param tokenIndexFrom the token to sell
* @param tokenIndexTo the token to buy
* @param dx the number of tokens to sell. If the token charges a fee on transfers,
* use the amount that gets transferred after the fee.
* @return dy the number of tokens the user will get
* @return dyFee the associated fee
*/
function _calculateSwap(
Swap storage self,
uint8 tokenIndexFrom,
uint8 tokenIndexTo,
uint256 dx
) internal view returns (uint256 dy, uint256 dyFee) {
uint256[] memory xp = _xp(self);
require(
tokenIndexFrom < xp.length && tokenIndexTo < xp.length,
"Token index out of range"
);
uint256 x =
dx.mul(self.tokenPrecisionMultipliers[tokenIndexFrom]).add(
xp[tokenIndexFrom]
);
uint256 y = getY(self, tokenIndexFrom, tokenIndexTo, x, xp);
dy = xp[tokenIndexTo].sub(y).sub(1);
dyFee = dy.mul(self.swapFee).div(FEE_DENOMINATOR);
dy = dy.sub(dyFee).div(self.tokenPrecisionMultipliers[tokenIndexTo]);
}
/**
* @notice A simple method to calculate amount of each underlying
* tokens that is returned upon burning given amount of
* LP tokens
*
* @param account the address that is removing liquidity. required for withdraw fee calculation
* @param amount the amount of LP tokens that would to be burned on
* withdrawal
* @return array of amounts of tokens user will receive
*/
function calculateRemoveLiquidity(
Swap storage self,
address account,
uint256 amount
) external view returns (uint256[] memory) {
return _calculateRemoveLiquidity(self, account, amount);
}
function _calculateRemoveLiquidity(
Swap storage self,
address account,
uint256 amount
) internal view returns (uint256[] memory) {
uint256 totalSupply = self.lpToken.totalSupply();
require(amount <= totalSupply, "Cannot exceed total supply");
uint256 feeAdjustedAmount =
amount
.mul(
FEE_DENOMINATOR.sub(calculateCurrentWithdrawFee(self, account))
)
.div(FEE_DENOMINATOR);
uint256[] memory amounts = new uint256[](self.pooledTokens.length);
for (uint256 i = 0; i < self.pooledTokens.length; i++) {
amounts[i] = self.balances[i].mul(feeAdjustedAmount).div(
totalSupply
);
}
return amounts;
}
/**
* @notice Calculate the fee that is applied when the given user withdraws.
* Withdraw fee decays linearly over 4 weeks.
* @param user address you want to calculate withdraw fee of
* @return current withdraw fee of the user
*/
function calculateCurrentWithdrawFee(Swap storage self, address user)
public
view
returns (uint256)
{
uint256 endTime = self.depositTimestamp[user].add(4 weeks);
if (endTime > block.timestamp) {
uint256 timeLeftover = endTime.sub(block.timestamp);
return
self
.defaultWithdrawFee
.mul(self.withdrawFeeMultiplier[user])
.mul(timeLeftover)
.div(4 weeks)
.div(FEE_DENOMINATOR);
}
return 0;
}
/**
* @notice A simple method to calculate prices from deposits or
* withdrawals, excluding fees but including slippage. This is
* helpful as an input into the various "min" parameters on calls
* to fight front-running
*
* @dev This shouldn't be used outside frontends for user estimates.
*
* @param self Swap struct to read from
* @param account address of the account depositing or withdrawing tokens
* @param amounts an array of token amounts to deposit or withdrawal,
* corresponding to pooledTokens. The amount should be in each
* pooled token's native precision. If a token charges a fee on transfers,
* use the amount that gets transferred after the fee.
* @param deposit whether this is a deposit or a withdrawal
* @return if deposit was true, total amount of lp token that will be minted and if
* deposit was false, total amount of lp token that will be burned
*/
function calculateTokenAmount(
Swap storage self,
address account,
uint256[] calldata amounts,
bool deposit
) external view returns (uint256) {
uint256 numTokens = self.pooledTokens.length;
uint256 a = _getAPrecise(self);
uint256 d0 = getD(_xp(self, self.balances), a);
uint256[] memory balances1 = self.balances;
for (uint256 i = 0; i < numTokens; i++) {
if (deposit) {
balances1[i] = balances1[i].add(amounts[i]);
} else {
balances1[i] = balances1[i].sub(
amounts[i],
"Cannot withdraw more than available"
);
}
}
uint256 d1 = getD(_xp(self, balances1), a);
uint256 totalSupply = self.lpToken.totalSupply();
if (deposit) {
return d1.sub(d0).mul(totalSupply).div(d0);
} else {
return
d0.sub(d1).mul(totalSupply).div(d0).mul(FEE_DENOMINATOR).div(
FEE_DENOMINATOR.sub(
calculateCurrentWithdrawFee(self, account)
)
);
}
}
/**
* @notice return accumulated amount of admin fees of the token with given index
* @param self Swap struct to read from
* @param index Index of the pooled token
* @return admin balance in the token's precision
*/
function getAdminBalance(Swap storage self, uint256 index)
external
view
returns (uint256)
{
require(index < self.pooledTokens.length, "Token index out of range");
return
self.pooledTokens[index].balanceOf(address(this)).sub(
self.balances[index]
);
}
/**
* @notice internal helper function to calculate fee per token multiplier used in
* swap fee calculations
* @param self Swap struct to read from
*/
function _feePerToken(Swap storage self) internal view returns (uint256) {
return
self.swapFee.mul(self.pooledTokens.length).div(
self.pooledTokens.length.sub(1).mul(4)
);
}
/*** STATE MODIFYING FUNCTIONS ***/
/**
* @notice swap two tokens in the pool
* @param self Swap struct to read from and write to
* @param tokenIndexFrom the token the user wants to sell
* @param tokenIndexTo the token the user wants to buy
* @param dx the amount of tokens the user wants to sell
* @param minDy the min amount the user would like to receive, or revert.
* @return amount of token user received on swap
*/
function swap(
Swap storage self,
uint8 tokenIndexFrom,
uint8 tokenIndexTo,
uint256 dx,
uint256 minDy
) external returns (uint256) {
require(
dx <= self.pooledTokens[tokenIndexFrom].balanceOf(msg.sender),
"Cannot swap more than you own"
);
// Transfer tokens first to see if a fee was charged on transfer
uint256 beforeBalance =
self.pooledTokens[tokenIndexFrom].balanceOf(address(this));
self.pooledTokens[tokenIndexFrom].safeTransferFrom(
msg.sender,
address(this),
dx
);
// Use the actual transferred amount for AMM math
uint256 transferredDx =
self.pooledTokens[tokenIndexFrom].balanceOf(address(this)).sub(
beforeBalance
);
(uint256 dy, uint256 dyFee) =
_calculateSwap(self, tokenIndexFrom, tokenIndexTo, transferredDx);
require(dy >= minDy, "Swap didn't result in min tokens");
uint256 dyAdminFee =
dyFee.mul(self.adminFee).div(FEE_DENOMINATOR).div(
self.tokenPrecisionMultipliers[tokenIndexTo]
);
self.balances[tokenIndexFrom] = self.balances[tokenIndexFrom].add(
transferredDx
);
self.balances[tokenIndexTo] = self.balances[tokenIndexTo].sub(dy).sub(
dyAdminFee
);
self.pooledTokens[tokenIndexTo].safeTransfer(msg.sender, dy);
emit TokenSwap(
msg.sender,
transferredDx,
dy,
tokenIndexFrom,
tokenIndexTo
);
return dy;
}
/**
* @notice Add liquidity to the pool
* @param self Swap struct to read from and write to
* @param amounts the amounts of each token to add, in their native precision
* @param minToMint the minimum LP tokens adding this amount of liquidity
* should mint, otherwise revert. Handy for front-running mitigation
* @return amount of LP token user received
*/
function addLiquidity(
Swap storage self,
uint256[] memory amounts,
uint256 minToMint
) external returns (uint256) {
require(
amounts.length == self.pooledTokens.length,
"Amounts must match pooled tokens"
);
uint256[] memory fees = new uint256[](self.pooledTokens.length);
uint256 lpTotalSupply = self.lpToken.totalSupply();
// current state
AddLiquidityInfo memory v = AddLiquidityInfo(0, 0, 0, 0);
if (lpTotalSupply != 0) {
v.d0 = getD(self);
}
uint256[] memory newBalances = self.balances;
for (uint256 i = 0; i < self.pooledTokens.length; i++) {
require(
lpTotalSupply != 0 || amounts[i] > 0,
"Must supply all tokens in pool"
);
// Transfer tokens first to see if a fee was charged on transfer
if (amounts[i] != 0) {
uint256 beforeBalance =
self.pooledTokens[i].balanceOf(address(this));
self.pooledTokens[i].safeTransferFrom(
msg.sender,
address(this),
amounts[i]
);
// Update the amounts[] with actual transfer amount
amounts[i] = self.pooledTokens[i].balanceOf(address(this)).sub(
beforeBalance
);
}
newBalances[i] = self.balances[i].add(amounts[i]);
}
// invariant after change
v.preciseA = _getAPrecise(self);
v.d1 = getD(_xp(self, newBalances), v.preciseA);
require(v.d1 > v.d0, "D should increase");
// updated to reflect fees and calculate the user's LP tokens
v.d2 = v.d1;
if (lpTotalSupply != 0) {
uint256 feePerToken = _feePerToken(self);
for (uint256 i = 0; i < self.pooledTokens.length; i++) {
uint256 idealBalance = v.d1.mul(self.balances[i]).div(v.d0);
fees[i] = feePerToken
.mul(idealBalance.difference(newBalances[i]))
.div(FEE_DENOMINATOR);
self.balances[i] = newBalances[i].sub(
fees[i].mul(self.adminFee).div(FEE_DENOMINATOR)
);
newBalances[i] = newBalances[i].sub(fees[i]);
}
v.d2 = getD(_xp(self, newBalances), v.preciseA);
} else {
// the initial depositor doesn't pay fees
self.balances = newBalances;
}
uint256 toMint;
uint256 toMintFee;
uint256 toMintUser;
if (lpTotalSupply == 0) {
toMint = v.d1;
} else {
toMint = v.d2.sub(v.d0).mul(lpTotalSupply).div(v.d0);
}
require(toMint >= minToMint, "Couldn't mint min requested");
// if deposit fee is none, mint full amount
if (self.defaultDepositFee == 0) {
self.lpToken.mint(msg.sender, toMint);
} else {
// mint the user's LP tokens minus the deposit fee
toMintFee = toMint.mul(self.defaultDepositFee).div(FEE_DENOMINATOR);
toMintUser = toMint.sub(toMintFee);
self.lpToken.mint(self.devaddr, toMintFee);
self.lpToken.mint(msg.sender, toMintUser);
}
emit AddLiquidity(
msg.sender,
amounts,
fees,
v.d1,
lpTotalSupply + toMint
);
return toMint;
}
/**
* @notice Update the withdraw fee for `user`. If the user is currently
* not providing liquidity in the pool, sets to default value. If not, recalculate
* the starting withdraw fee based on the last deposit's time & amount relative
* to the new deposit.
*
* @param self Swap struct to read from and write to
* @param user address of the user depositing tokens
* @param toMint amount of pool tokens to be minted
*/
function updateUserWithdrawFee(
Swap storage self,
address user,
uint256 toMint
) external {
_updateUserWithdrawFee(self, user, toMint);
}
function _updateUserWithdrawFee(
Swap storage self,
address user,
uint256 toMint
) internal {
// If token is transferred to address 0 (or burned), don't update the fee.
if (user == address(0)) {
return;
}
if (self.defaultWithdrawFee == 0) {
// If current fee is set to 0%, set multiplier to FEE_DENOMINATOR
self.withdrawFeeMultiplier[user] = FEE_DENOMINATOR;
} else {
// Otherwise, calculate appropriate discount based on last deposit amount
uint256 currentFee = calculateCurrentWithdrawFee(self, user);
uint256 currentBalance = self.lpToken.balanceOf(user);