// SPDX-License-Identifier: AGPL-3.0-or-later pragma solidity ^0.8.13; import "forge-std/Test.sol"; import "openzeppelin-contracts/contracts/interfaces/IERC20.sol"; import {ISwapAdapter} from "src/interfaces/ISwapAdapter.sol"; import "src/interfaces/ISwapAdapterTypes.sol"; import "src/libraries/FractionMath.sol"; contract AdapterTest is Test, ISwapAdapterTypes { using FractionMath for Fraction; uint256 constant pricePrecision = 10e24; string[] public stringPctgs = ["0%", "0.01%", "50%", "100%"]; // @notice Test the behavior of a swap adapter for a list of pools // @dev Computes limits, prices, and swaps on the pools on both directions // for different // sell amounts. Asserts that the prices behaves as expected. // @param adapter The swap adapter to test // @param poolIds The list of pool ids to test function testPoolBehaviour(ISwapAdapter adapter, bytes32[] memory poolIds) public { bool hasPriceImpact = !hasCapability( adapter.getCapabilities(poolIds[0], address(0), address(0)), Capability.ConstantPrice ); for (uint256 i = 0; i < poolIds.length; i++) { address[] memory tokens = adapter.getTokens(poolIds[i]); IERC20(tokens[0]).approve(address(adapter), type(uint256).max); testPricesForPair( adapter, poolIds[i], tokens[0], tokens[1], hasPriceImpact ); testPricesForPair( adapter, poolIds[i], tokens[1], tokens[0], hasPriceImpact ); } } // Prices should: // 1. Be monotonic decreasing // 2. Be positive // 3. Always be >= the executed price and >= the price after the swap function testPricesForPair( ISwapAdapter adapter, bytes32 poolId, address tokenIn, address tokenOut, bool hasPriceImpact ) internal { uint256 sellLimit = adapter.getLimits(poolId, tokenIn, tokenOut)[0]; assertGt(sellLimit, 0, "Sell limit should be greater than 0"); console2.log( "TEST: Testing prices for pair %s -> %s. Sell limit: %d", tokenIn, tokenOut, sellLimit ); uint256[] memory amounts = calculateTestAmounts(sellLimit); Fraction[] memory prices = adapter.price(poolId, tokenIn, tokenOut, amounts); assertGt( fractionToInt(prices[0]), fractionToInt(prices[prices.length - 1]), "Price at limit should be smaller than price at 0" ); console2.log( "TEST: Price at 0: %d, price at sell limit: %d", fractionToInt(prices[0]), fractionToInt(prices[prices.length - 1]) ); console2.log("TEST: Testing behavior for price at 0"); assertGt(prices[0].numerator, 0, "Nominator shouldn't be 0"); assertGt(prices[0].denominator, 0, "Denominator shouldn't be 0"); Trade memory trade; deal(tokenIn, address(this), 2 * amounts[amounts.length - 1]); for (uint256 j = 1; j < amounts.length; j++) { console2.log( "TEST: Testing behavior for price at %s of limit: %d", stringPctgs[j], amounts[j] ); uint256 priceAtAmount = fractionToInt(prices[j]); assertGt(prices[j].numerator, 0, "Nominator shouldn't be 0"); assertGt(prices[j].denominator, 0, "Denominator shouldn't be 0"); console2.log("TEST: Swapping %d of %s", amounts[j], tokenIn); trade = adapter.swap( poolId, tokenIn, tokenOut, OrderSide.Sell, amounts[j] ); uint256 executedPrice = trade.calculatedAmount * pricePrecision / amounts[j]; uint256 priceAfterSwap = fractionToInt(trade.price); console2.log("TEST: Pool price: %d", priceAtAmount); console2.log("TEST: Executed price: %d", executedPrice); console2.log("TEST: Price after swap: %d", priceAfterSwap); if (hasPriceImpact) { assertGt( priceAtAmount, executedPrice, "Price should be greated than executed price." ); assertGt( executedPrice, priceAfterSwap, "Executed price should be greater than price after swap." ); assertGt( priceAtAmount, priceAfterSwap, "Price should be greated than price after swap." ); } else { assertGe( priceAtAmount, executedPrice, "Price should be greated than executed price." ); assertGe( executedPrice, priceAfterSwap, "Executed price should be greater than price after swap." ); assertGe( priceAtAmount, priceAfterSwap, "Price should be greated than price after swap." ); } } uint256 amountAboveLimit = sellLimit * 105 / 100; bool hasHardLimits = hasCapability( adapter.getCapabilities(poolId, tokenIn, tokenOut), Capability.HardLimits ); if (hasHardLimits) { testRevertAboveLimit( adapter, poolId, tokenIn, tokenOut, amountAboveLimit ); } else { testOperationsAboveLimit( adapter, poolId, tokenIn, tokenOut, amountAboveLimit ); } } function testRevertAboveLimit( ISwapAdapter adapter, bytes32 poolId, address tokenIn, address tokenOut, uint256 amountAboveLimit ) internal { console2.log("TEST: Testing revert behavior above the sell limit"); uint256[] memory aboveLimitArray = new uint256[](1); aboveLimitArray[0] = amountAboveLimit; try adapter.price(poolId, tokenIn, tokenOut, aboveLimitArray) { revert("Pool shouldn't be fetch prices above the sell limit"); } catch Error(string memory s) { console2.log( "TEST: Expected error when fetching price above limit: %s", s ); } try adapter.swap( poolId, tokenIn, tokenOut, OrderSide.Sell, aboveLimitArray[0] ) { revert("Pool shouldn't be able to swap above the sell limit"); } catch Error(string memory s) { console2.log( "TEST: Expected error when swapping above limit: %s", s ); } } function testOperationsAboveLimit( ISwapAdapter adapter, bytes32 poolId, address tokenIn, address tokenOut, uint256 amountAboveLimit ) internal { console2.log("TEST: Testing operations above the sell limit"); uint256[] memory aboveLimitArray = new uint256[](1); aboveLimitArray[0] = amountAboveLimit; adapter.price(poolId, tokenIn, tokenOut, aboveLimitArray); adapter.swap( poolId, tokenIn, tokenOut, OrderSide.Sell, aboveLimitArray[0] ); } function calculateTestAmounts(uint256 limit) internal pure returns (uint256[] memory) { uint256[] memory amounts = new uint256[](4); amounts[0] = 0; amounts[1] = limit / 10000; amounts[2] = limit / 2; amounts[3] = limit; return amounts; } function fractionToInt(Fraction memory price) public pure returns (uint256) { return price.numerator * pricePrecision / price.denominator; } function hasCapability( Capability[] memory capabilities, Capability capability ) internal pure returns (bool) { for (uint256 i = 0; i < capabilities.length; i++) { if (capabilities[i] == capability) { return true; } } return false; } }