package exchanges import ( "fmt" "math/big" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/ethclient" "github.com/fraktal/mev-beta/internal/logger" "github.com/fraktal/mev-beta/pkg/math" ) // UniswapV4PoolDetector implements PoolDetector for Uniswap V4 type UniswapV4PoolDetector struct { client *ethclient.Client logger *logger.Logger config *ExchangeConfig } // NewUniswapV4PoolDetector creates a new Uniswap V4 pool detector func NewUniswapV4PoolDetector(client *ethclient.Client, logger *logger.Logger, config *ExchangeConfig) *UniswapV4PoolDetector { return &UniswapV4PoolDetector{ client: client, logger: logger, config: config, } } // GetAllPools returns all pools containing the specified tokens func (d *UniswapV4PoolDetector) GetAllPools(token0, token1 common.Address) ([]common.Address, error) { // In a real implementation, this would query the Uniswap V4 hook contracts // For now, we'll return an empty slice return []common.Address{}, nil } // GetPoolForPair returns the pool address for a specific token pair func (d *UniswapV4PoolDetector) GetPoolForPair(token0, token1 common.Address) (common.Address, error) { // Calculate pool address using Uniswap V4 formula with hooks // In a real implementation, this would call the pool manager poolAddress := common.HexToAddress("0x0") // Placeholder // For now, return empty address to indicate pool not found return poolAddress, nil } // GetSupportedFeeTiers returns supported fee tiers for Uniswap V4 (varies by pool) func (d *UniswapV4PoolDetector) GetSupportedFeeTiers() []int64 { // Uniswap V4 pools can have different fee tiers return []int64{100, 500, 3000, 10000} // 0.01%, 0.05%, 0.3%, 1% in basis points } // GetPoolType returns the pool type func (d *UniswapV4PoolDetector) GetPoolType() string { return "uniswap_v4_concentrated" } // UniswapV4LiquidityFetcher implements LiquidityFetcher for Uniswap V4 type UniswapV4LiquidityFetcher struct { client *ethclient.Client logger *logger.Logger config *ExchangeConfig engine *math.ExchangePricingEngine } // NewUniswapV4LiquidityFetcher creates a new Uniswap V4 liquidity fetcher func NewUniswapV4LiquidityFetcher(client *ethclient.Client, logger *logger.Logger, config *ExchangeConfig, engine *math.ExchangePricingEngine) *UniswapV4LiquidityFetcher { return &UniswapV4LiquidityFetcher{ client: client, logger: logger, config: config, engine: engine, } } // GetPoolData fetches pool information for Uniswap V4 func (f *UniswapV4LiquidityFetcher) GetPoolData(poolAddress common.Address) (*math.PoolData, error) { // In a real implementation, this would call the pool contract to get tick, liquidity, and other data // For now, return a placeholder pool data with Uniswap V4-specific fields fee, err := math.NewUniversalDecimal(big.NewInt(300), 4, "FEE") // 0.3% standard fee if err != nil { return nil, fmt.Errorf("error creating fee decimal: %w", err) } reserve0Value := new(big.Int) reserve0Value.SetString("1000000000000000000000", 10) // WETH reserve0, err := math.NewUniversalDecimal(reserve0Value, 18, "RESERVE0") if err != nil { return nil, fmt.Errorf("error creating reserve0 decimal: %w", err) } reserve1Value := new(big.Int) reserve1Value.SetString("1000000000000", 10) // USDC reserve1, err := math.NewUniversalDecimal(reserve1Value, 6, "RESERVE1") if err != nil { return nil, fmt.Errorf("error creating reserve1 decimal: %w", err) } return &math.PoolData{ Address: poolAddress.Hex(), ExchangeType: math.ExchangeUniswapV4, Fee: fee, Token0: math.TokenInfo{Address: "0x0", Symbol: "WETH", Decimals: 18}, Token1: math.TokenInfo{Address: "0x1", Symbol: "USDC", Decimals: 6}, Reserve0: reserve0, Reserve1: reserve1, SqrtPriceX96: big.NewInt(0), // Would be populated with actual sqrtPriceX96 Tick: big.NewInt(0), // Would be populated with actual tick Liquidity: big.NewInt(0), // Would be populated with actual liquidity }, nil } // GetTokenReserves fetches reserves for a specific token pair in a pool func (f *UniswapV4LiquidityFetcher) GetTokenReserves(poolAddress, token0, token1 common.Address) (*big.Int, *big.Int, error) { // In a real implementation, this would query the pool contract // For now, return placeholder values reserve0 := new(big.Int) reserve0.SetString("1000000000000000000000", 10) // WETH reserve1 := new(big.Int) reserve1.SetString("1000000000000", 10) // USDC return reserve0, reserve1, nil } // GetPoolPrice calculates the price of token1 in terms of token0 func (f *UniswapV4LiquidityFetcher) GetPoolPrice(poolAddress common.Address) (*big.Float, error) { poolData, err := f.GetPoolData(poolAddress) if err != nil { return nil, err } pricer, err := f.engine.GetExchangePricer(poolData.ExchangeType) if err != nil { return nil, err } spotPrice, err := pricer.GetSpotPrice(poolData) if err != nil { return nil, err } // Convert the UniversalDecimal Value to a *big.Float result := new(big.Float).SetInt(spotPrice.Value) return result, nil } // GetLiquidityDepth calculates the liquidity depth for an amount func (f *UniswapV4LiquidityFetcher) GetLiquidityDepth(poolAddress, tokenIn common.Address, amount *big.Int) (*big.Int, error) { // In a real implementation, this would calculate liquidity with Uniswap V4's concentrated liquidity model return amount, nil } // UniswapV4SwapRouter implements SwapRouter for Uniswap V4 type UniswapV4SwapRouter struct { client *ethclient.Client logger *logger.Logger config *ExchangeConfig engine *math.ExchangePricingEngine } // NewUniswapV4SwapRouter creates a new Uniswap V4 swap router func NewUniswapV4SwapRouter(client *ethclient.Client, logger *logger.Logger, config *ExchangeConfig, engine *math.ExchangePricingEngine) *UniswapV4SwapRouter { return &UniswapV4SwapRouter{ client: client, logger: logger, config: config, engine: engine, } } // CalculateSwap calculates the expected output amount for a swap func (r *UniswapV4SwapRouter) CalculateSwap(tokenIn, tokenOut common.Address, amountIn *big.Int) (*big.Int, error) { // Find pool for the token pair poolAddress, err := r.findPoolForPair(tokenIn, tokenOut) if err != nil { return nil, fmt.Errorf("failed to find pool for pair: %w", err) } // Get pool data poolData, err := r.GetPoolData(poolAddress) if err != nil { return nil, fmt.Errorf("failed to get pool data: %w", err) } // Create a UniversalDecimal from the amountIn decimalAmountIn, err := math.NewUniversalDecimal(amountIn, 18, "AMOUNT_IN") if err != nil { return nil, fmt.Errorf("error creating amount in decimal: %w", err) } // Get the pricer pricer, err := r.engine.GetExchangePricer(poolData.ExchangeType) if err != nil { return nil, err } // Calculate amount out using Uniswap V4's concentrated liquidity formula amountOut, err := pricer.CalculateAmountOut(decimalAmountIn, poolData) if err != nil { return nil, err } return amountOut.Value, nil } // findPoolForPair finds the pool address for a given token pair func (r *UniswapV4SwapRouter) findPoolForPair(token0, token1 common.Address) (common.Address, error) { // In a real implementation, this would query the Uniswap V4 pool manager // For now, return a placeholder address return common.HexToAddress("0x0"), nil } // GetPoolData is a helper to fetch pool data (for internal use) func (r *UniswapV4SwapRouter) GetPoolData(poolAddress common.Address) (*math.PoolData, error) { fetcher := NewUniswapV4LiquidityFetcher(r.client, r.logger, r.config, r.engine) return fetcher.GetPoolData(poolAddress) } // GenerateSwapData generates the calldata for a swap transaction func (r *UniswapV4SwapRouter) GenerateSwapData(tokenIn, tokenOut common.Address, amountIn, minAmountOut *big.Int, deadline *big.Int) ([]byte, error) { // In a real implementation, this would generate the encoded function call // For Uniswap V4, this would typically be exactInputSingle or exactOutputSingle return []byte{}, nil } // GetSwapRoute returns the route for a swap (for Uniswap V4, typically direct within a pool) func (r *UniswapV4SwapRouter) GetSwapRoute(tokenIn, tokenOut common.Address) ([]common.Address, error) { // For Uniswap V4, the route is usually direct within a concentrated liquidity pool // For now, return the token pair as a direct route return []common.Address{tokenIn, tokenOut}, nil } // ValidateSwap validates a swap before execution func (r *UniswapV4SwapRouter) ValidateSwap(tokenIn, tokenOut common.Address, amountIn *big.Int) error { if amountIn.Sign() <= 0 { return fmt.Errorf("amountIn must be positive") } if tokenIn == tokenOut { return fmt.Errorf("tokenIn and tokenOut cannot be the same") } if tokenIn == common.HexToAddress("0x0") || tokenOut == common.HexToAddress("0x0") { return fmt.Errorf("invalid token addresses") } return nil } // RegisterUniswapV4WithRegistry registers Uniswap V4 implementation with the exchange registry func RegisterUniswapV4WithRegistry(registry *ExchangeRegistry) error { config := &ExchangeConfig{ Type: math.ExchangeUniswapV4, Name: "Uniswap V4", FactoryAddress: common.HexToAddress("0x000000000022D473030F116dDEE9F6B7653f39281251"), // Uniswap V4 Pool Manager (placeholder) RouterAddress: common.HexToAddress("0x000000000022D473030F116dDEE9F6B7653f39281252"), // Uniswap V4 Router (placeholder) PoolInitCodeHash: "0x0000000000000000000000000000000000000000000000000000000000000000", // Placeholder SwapSelector: []byte{0x44, 0x13, 0x70, 0x64}, // exactInputSingle StableSwapSelector: []byte{0x44, 0x13, 0x70, 0x65}, // exactOutputSingle ChainID: 1, // Ethereum mainnet SupportsFlashSwaps: true, RequiresApproval: true, MaxHops: 2, DefaultSlippagePercent: 0.5, Url: "https://uniswap.org", ApiUrl: "https://api.uniswap.org", } registry.exchanges[math.ExchangeUniswapV4] = config // Register the implementations as well return nil }