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Stable2::calcLpTokenSupply() - The function cannot convert under certain circumstances, DoSing calcReserveAtRatioLiquidity
Lines of code
Vulnerability details
Impact
calcLpTokenSupply is used in both calcReserveAtRatioLiquidity and calcReserveAtRatioSwap, we'll focus on calcReserveAtRatioLiquidity.
calcLpTokenSupply is called inside calcRate here:
solidityfunction calcReserveAtRatioLiquidity( uint256[] calldata reserves, uint256 j, uint256[] calldata ratios, bytes calldata data ) external view returns (uint256 reserve) { ... for (uint256 k; k < 255; k++) { scaledReserves[j] = updateReserve(pd, scaledReserves[j]); // calculate new price from reserves: pd.newPrice = calcRate(scaledReserves, i, j, abi.encode(18, 18)); ...
Inside we call the function:
solidityfunction calcRate( uint256[] memory reserves, uint256 i, uint256 j, bytes memory data ) public view returns (uint256 rate) { uint256[] memory decimals = decodeWellData(data); uint256[] memory scaledReserves = getScaledReserves(reserves, decimals); // calc lp token supply (note: `scaledReserves` is scaled up, and does not require bytes). uint256 lpTokenSupply = calcLpTokenSupply(scaledReserves, abi.encode(18, 18)); rate = _calcRate(scaledReserves, i, j, lpTokenSupply); }
Note that the only change to calcLpTokenSupply is the added revert on the last line of the function.
solidityfunction calcLpTokenSupply( uint256[] memory reserves, bytes memory data ) public view returns (uint256 lpTokenSupply) { if (reserves[0] == 0 && reserves[1] == 0) return 0; uint256[] memory decimals = decodeWellData(data); // scale reserves to 18 decimals. uint256[] memory scaledReserves = getScaledReserves(reserves, decimals); uint256 Ann = a * N * N; uint256 sumReserves = scaledReserves[0] + scaledReserves[1]; lpTokenSupply = sumReserves; for (uint256 i = 0; i < 255; i++) { uint256 dP = lpTokenSupply; // If division by 0, this will be borked: only withdrawal will work. And that is good dP = dP * lpTokenSupply / (scaledReserves[0] * N); dP = dP * lpTokenSupply / (scaledReserves[1] * N); uint256 prevReserves = lpTokenSupply; lpTokenSupply = (Ann * sumReserves / A_PRECISION + (dP * N)) * lpTokenSupply / (((Ann - A_PRECISION) * lpTokenSupply / A_PRECISION) + ((N + 1) * dP)); // Equality with the precision of 1 if (lpTokenSupply > prevReserves) { if (lpTokenSupply - prevReserves <= 1) return lpTokenSupply; } else { if (prevReserves - lpTokenSupply <= 1) return lpTokenSupply; } } revert("Non convergence: calcLpTokenSupply"); }
The issue here lies that calcLpTokenSupply reverts under certain circumstances since it cannot converge, which makes the whole call to calcReserveAtRatioLiquidity revert.
We'll investigate this further inside the PoC section.
Proof of Concept
Paste the following inside BeanstalkStable2LiquidityTest and run forge test --mt test_calcReserveAtRatioLiquidity_equal_equalPositive -vv
This is a rough test to loop through some of the cases in Stable2LUT1.
solidityfunction test_calcReserveAtRatioLiquidity_equal_equalPositive() public view { uint256[] memory reserves = new uint256[](2); reserves[0] = 1987e18; reserves[1] = 12345e8; uint256[] memory ratios = new uint256[](2); ratios[0] = 1e18; ratios[1] = 1e18; for(uint i; i < 10000; i++) { _f.calcReserveAtRatioLiquidity(reserves, 0, ratios, data); ratios[0] += 0.003e18; } }
You'll notice that the test reverts with:
[FAIL. Reason: revert: Non convergence: calcLpTokenSupply]
The values that it reverts with are:
solidityRatios[0]: 7195000000000000000 Ratios[1]: 1000000000000000000 Target price: 138927 High Price: 277020 Low Price: 1083 Current price: 1083 (price is closer to lowPrice)
This is when we hit this case in Stable2LUT1:
solidityif (price < 0.001083e6) { revert("LUT: Invalid price"); } else { return -> PriceData(0.27702e6, 0, 9.646293093274934449e18, 0.001083e6, 0, 2000e18, 1e18); }
Here are the last few iterations of calcLpTokenSupply:
solidityCurrent Lp token supply: 237151473819804594336 Prev Lp token supply: 237151473819804594338 ------------------------------------------- Current Lp token supply: 237151473819804594338 Prev Lp token supply: 237151473819804594336 ------------------------------------------- Current Lp token supply: 237151473819804594336 Prev Lp token supply: 237151473819804594338 ------------------------------------------- Current Lp token supply: 237151473819804594338 Prev Lp token supply: 237151473819804594336 ------------------------------------------- Current Lp token supply: 237151473819804594336 Prev Lp token supply: 237151473819804594338 ------------------------------------------- Current Lp token supply: 237151473819804594338 Prev Lp token supply: 237151473819804594336 -------------------------------------------
As you can see the values "loop" +-2, which makes it impossible to converge, since the difference has to be <= 1 so it converges.
Something to note is that even if we change the reserves in the test, the test continues failing with the same error, but every test fails when we hit this specific case in the lookup table and the price is closer to the lowPrice.
PriceData(0.27702e6, 0, 9.646293093274934449e18, 0.001083e6, 0, 2000e18, 1e18);
It's unclear what causes this "looping" to occur, so it's hard to say what the root cause is.
Something interesting is that this started happening once the revert was introduced, the last audit didn't have it, but the code still worked. Then it didn't revert it just returned the last lpTokenSupply.
Also note that the underlying issue is in calcLpTokenSupply, so if the function is used on it's own it can still revert, but it happens much more often when calcReserveAtRatioLiquidity is used.
Tools Used
Manual Review Foundry
Recommended Mitigation Steps
It's very hard to recommend a fix here, as many tweaks can fix the issue. We can recommend:
- Passing a flag to
calcLpTokenSupply, if true then if the function doesn't converge it won't revert. - Tweaking the
PriceDatavalues for the specific case in the lookup table, narrowing down the range seems to fix the issue.
Assessed type
DoS