sol-trade-sdk 4.0.3

pub mod common;
pub mod constants;
pub mod instruction;
pub mod perf;
pub mod swqos;
pub mod trading;
pub mod utils;
use crate::common::nonce_cache::DurableNonceInfo;
use crate::common::sdk_log;
use crate::common::GasFeeStrategy;
use crate::common::{InfrastructureConfig, TradeConfig};
#[cfg(feature = "perf-trace")]
use crate::constants::trade::trade::DEFAULT_SLIPPAGE;
use crate::constants::SOL_TOKEN_ACCOUNT;
use crate::constants::USD1_TOKEN_ACCOUNT;
use crate::constants::USDC_TOKEN_ACCOUNT;
use crate::constants::WSOL_TOKEN_ACCOUNT;
use crate::swqos::common::TradeError;
use crate::swqos::SwqosClient;
use crate::swqos::SwqosConfig;
use crate::swqos::TradeType;
// Re-export for SWQOS HTTP/QUIC choice in SwqosConfig (e.g. Astralane)
pub use crate::swqos::SwqosTransport;
use crate::trading::core::params::BonkParams;
use crate::trading::core::params::DexParamEnum;
use crate::trading::core::params::MeteoraDammV2Params;
use crate::trading::core::params::PumpFunParams;
use crate::trading::core::params::PumpSwapParams;
use crate::trading::core::params::RaydiumAmmV4Params;
use crate::trading::core::params::RaydiumCpmmParams;
use crate::trading::factory::DexType;
use crate::trading::MiddlewareManager;
use crate::trading::SwapParams;
use crate::trading::TradeFactory;
use common::SolanaRpcClient;
use parking_lot::Mutex;
use rustls::crypto::{ring::default_provider, CryptoProvider};
use solana_sdk::hash::Hash;
use solana_sdk::message::AddressLookupTableAccount;
use solana_sdk::signer::Signer;
use solana_sdk::{pubkey::Pubkey, signature::Keypair, signature::Signature};
use std::sync::Arc;
#[allow(unused_imports)]
use tracing::{debug, error, info, warn};

/// Single place to validate that protocol params match the given DEX type (avoids duplicate match in buy/sell).
#[inline(always)]
fn validate_protocol_params(dex_type: DexType, params: &DexParamEnum) -> bool {
    match dex_type {
        DexType::PumpFun => params.as_any().downcast_ref::<PumpFunParams>().is_some(),
        DexType::PumpSwap => params.as_any().downcast_ref::<PumpSwapParams>().is_some(),
        DexType::Bonk => params.as_any().downcast_ref::<BonkParams>().is_some(),
        DexType::RaydiumCpmm => params.as_any().downcast_ref::<RaydiumCpmmParams>().is_some(),
        DexType::RaydiumAmmV4 => params.as_any().downcast_ref::<RaydiumAmmV4Params>().is_some(),
        DexType::MeteoraDammV2 => params.as_any().downcast_ref::<MeteoraDammV2Params>().is_some(),
    }
}

/// 按 mint 查找池地址（通用入口，根据 DEX 类型分发，仅 PumpSwap 等已实现的类型会走优化路径）。
///
/// * `dex_type`：PumpSwap 时先走 PDA 再回退 getProgramAccounts，其他类型返回未实现错误。
pub async fn find_pool_by_mint(
    rpc: &SolanaRpcClient,
    mint: &Pubkey,
    dex_type: DexType,
) -> Result<Pubkey, anyhow::Error> {
    match dex_type {
        DexType::PumpSwap => crate::instruction::utils::pumpswap::find_pool(rpc, mint).await,
        _ => Err(anyhow::anyhow!("find_pool_by_mint not implemented for {:?}", dex_type)),
    }
}

/// Type of the token to buy
#[derive(Clone, PartialEq)]
pub enum TradeTokenType {
    SOL,
    WSOL,
    USD1,
    USDC,
}

/// Shared infrastructure components that can be reused across multiple wallets
///
/// This struct holds the expensive-to-initialize components (RPC client, SWQOS clients)
/// that are wallet-independent and can be shared when only the trading wallet changes.
pub struct TradingInfrastructure {
    /// Shared RPC client for blockchain interactions
    pub rpc: Arc<SolanaRpcClient>,
    /// Shared SWQOS clients for transaction priority and routing. Arc<Vec<..>> so cloning into SwapParams is a single Arc clone.
    pub swqos_clients: Arc<Vec<Arc<SwqosClient>>>,
    /// Configuration used to create this infrastructure
    pub config: InfrastructureConfig,
    /// Precomputed at init: min(swqos_clients.len(), 2/3 * num_cores). Not computed on trade hot path.
    pub max_sender_concurrency: usize,
    /// Precomputed at init: first max_sender_concurrency CoreIds for job affinity. Empty if no cores. Not computed on trade hot path.
    pub effective_core_ids: Arc<Vec<core_affinity::CoreId>>,
}

impl TradingInfrastructure {
    /// Create new shared infrastructure from configuration
    ///
    /// This performs the expensive initialization:
    /// - Creates RPC client with connection pool
    /// - Creates SWQOS clients (each with their own HTTP client)
    /// - Initializes rent cache and starts background updater
    pub async fn new(config: InfrastructureConfig) -> Self {
        // Install crypto provider (idempotent)
        if CryptoProvider::get_default().is_none() {
            let _ = default_provider()
                .install_default()
                .map_err(|e| anyhow::anyhow!("Failed to install crypto provider: {:?}", e));
        }

        // Create RPC client
        let rpc = Arc::new(SolanaRpcClient::new_with_commitment(
            config.rpc_url.clone(),
            config.commitment.clone(),
        ));

        // Initialize rent cache (with timeout so slow RPC doesn't block forever)
        const RENT_UPDATE_TIMEOUT: std::time::Duration = std::time::Duration::from_secs(15);
        match tokio::time::timeout(RENT_UPDATE_TIMEOUT, common::seed::update_rents(&rpc)).await {
            Ok(Ok(())) => {}
            Ok(Err(e)) => {
                if sdk_log::sdk_log_enabled() {
                    warn!(target: "sol_trade_sdk", "rent update failed: {}, using defaults", e);
                }
                common::seed::set_default_rents();
            }
            Err(_) => {
                if sdk_log::sdk_log_enabled() {
                    warn!(target: "sol_trade_sdk", "rent update timed out ({}s), using defaults; check RPC", RENT_UPDATE_TIMEOUT.as_secs());
                }
                common::seed::set_default_rents();
            }
        }
        common::seed::start_rent_updater(rpc.clone());

        // Create SWQOS clients with blacklist checking（单节点超时 5s，避免某一家卡死整段初始化）
        const SWQOS_CLIENT_TIMEOUT: std::time::Duration = std::time::Duration::from_secs(5);
        let mut swqos_clients: Vec<Arc<SwqosClient>> = vec![];
        for swqos in &config.swqos_configs {
            if swqos.is_blacklisted() {
                if sdk_log::sdk_log_enabled() {
                    warn!(target: "sol_trade_sdk", "⚠️ SWQOS {:?} is blacklisted, skipping", swqos.swqos_type());
                }
                continue;
            }
            match tokio::time::timeout(
                SWQOS_CLIENT_TIMEOUT,
                SwqosConfig::get_swqos_client(
                    config.rpc_url.clone(),
                    config.commitment.clone(),
                    swqos.clone(),
                    config.mev_protection,
                ),
            )
            .await
            {
                Ok(Ok(swqos_client)) => swqos_clients.push(swqos_client),
                Ok(Err(err)) => {
                    if sdk_log::sdk_log_enabled() {
                        warn!(
                            target: "sol_trade_sdk",
                            "failed to create {:?} swqos client: {err}. Excluding from swqos list",
                            swqos.swqos_type()
                        );
                    }
                }
                Err(_) => {
                    if sdk_log::sdk_log_enabled() {
                        warn!(
                            target: "sol_trade_sdk",
                            "swqos {:?} init timed out ({}s), skipping",
                            swqos.swqos_type(),
                            SWQOS_CLIENT_TIMEOUT.as_secs()
                        );
                    }
                }
            }
        }

        let swqos_count = swqos_clients.len();
        let (max_sender_concurrency, effective_core_ids) = {
            let num_cores = core_affinity::get_core_ids().map(|c| c.len()).unwrap_or(0);
            let max_by_cores = (num_cores * 2 / 3).max(1);
            let cap = swqos_count.min(max_by_cores).max(1);
            let ids = core_affinity::get_core_ids()
                .map(|all| {
                    let v: Vec<_> = all.into_iter().collect();
                    let len = v.len();
                    if config.swqos_cores_from_end && len >= cap {
                        v.into_iter().skip(len - cap).collect()
                    } else {
                        v.into_iter().take(cap).collect()
                    }
                })
                .unwrap_or_default();
            (cap, Arc::new(ids))
        };

        Self {
            rpc,
            swqos_clients: Arc::new(swqos_clients),
            config,
            max_sender_concurrency,
            effective_core_ids,
        }
    }
}

/// When using `TradeConfig::with_swqos_cores_from_end(true)`, returns the same "last N" core indices
/// that the infrastructure uses. Pass the result to `TradingClient::with_dedicated_sender_threads`
/// for 方式 C (组合使用): SWQOS on last N cores and dedicated sender threads pinned to those cores.
///
/// Returns `None` if core count cannot be determined. `swqos_count` is typically `swqos_configs.len()`.
pub fn recommended_sender_thread_core_indices(swqos_count: usize) -> Option<Vec<usize>> {
    let all = core_affinity::get_core_ids()?;
    let num_cores = all.len();
    if num_cores == 0 {
        return None;
    }
    let max_by_cores = (num_cores * 2 / 3).max(1);
    let cap = swqos_count.min(max_by_cores).max(1).min(num_cores);
    let start = num_cores.saturating_sub(cap);
    Some((start..num_cores).collect())
}

/// Main trading client for Solana DeFi protocols
///
/// `SolTradingSDK` provides a unified interface for trading across multiple Solana DEXs
/// including PumpFun, PumpSwap, Bonk, Raydium AMM V4, and Raydium CPMM.
/// It manages RPC connections, transaction signing, and SWQOS (Solana Web Quality of Service) settings.
pub struct TradingClient {
    /// The keypair used for signing all transactions
    pub payer: Arc<Keypair>,
    /// Shared infrastructure (RPC client, SWQOS clients)
    /// Can be shared across multiple TradingClient instances with different wallets
    pub infrastructure: Arc<TradingInfrastructure>,
    /// Optional middleware manager for custom transaction processing
    pub middleware_manager: Option<Arc<MiddlewareManager>>,
    /// Whether to use seed optimization for all ATA operations (default: true)
    /// Applies to all token account creations across buy and sell operations
    pub use_seed_optimize: bool,
    /// Internal: use dedicated sender threads (default false). Set via with_dedicated_sender_threads() for advanced use.
    pub use_dedicated_sender_threads: bool,
    /// Internal: core indices for dedicated sender threads. Trimmed to ≤ max_sender_concurrency at set.
    pub sender_thread_cores: Option<Arc<Vec<usize>>>,
    /// Internal: precomputed at infra init (min(swqos_count, 2/3*cores)). Not user-configurable.
    pub max_sender_concurrency: usize,
    /// Internal: precomputed at infra init for job affinity. Not user-configurable.
    pub effective_core_ids: Arc<Vec<core_affinity::CoreId>>,
    /// Whether to output all SDK logs (from TradeConfig.log_enabled).
    pub log_enabled: bool,
    /// Whether to check minimum tip per SWQOS (from TradeConfig.check_min_tip). Default false for lower latency.
    pub check_min_tip: bool,
}

static INSTANCE: Mutex<Option<Arc<TradingClient>>> = Mutex::new(None);

/// 🔄 向后兼容：SolanaTrade 别名
pub type SolanaTrade = TradingClient;

impl Clone for TradingClient {
    fn clone(&self) -> Self {
        Self {
            payer: self.payer.clone(),
            infrastructure: self.infrastructure.clone(),
            middleware_manager: self.middleware_manager.clone(),
            use_seed_optimize: self.use_seed_optimize,
            use_dedicated_sender_threads: self.use_dedicated_sender_threads,
            sender_thread_cores: self.sender_thread_cores.clone(),
            max_sender_concurrency: self.max_sender_concurrency,
            effective_core_ids: self.effective_core_ids.clone(),
            log_enabled: self.log_enabled,
            check_min_tip: self.check_min_tip,
        }
    }
}

/// Parameters for executing buy orders across different DEX protocols
///
/// Contains all necessary configuration for purchasing tokens, including
/// protocol-specific settings, account management options, and transaction preferences.
#[derive(Clone)]
pub struct TradeBuyParams {
    // Trading configuration
    /// The DEX protocol to use for the trade
    pub dex_type: DexType,
    /// Type of the token to buy
    pub input_token_type: TradeTokenType,
    /// Public key of the token to purchase
    pub mint: Pubkey,
    /// Amount of tokens to buy (in smallest token units)
    pub input_token_amount: u64,
    /// Optional slippage tolerance in basis points (e.g., 100 = 1%)
    pub slippage_basis_points: Option<u64>,
    /// Recent blockhash for transaction validity
    pub recent_blockhash: Option<Hash>,
    /// Protocol-specific parameters (PumpFun, Raydium, etc.)
    pub extension_params: DexParamEnum,
    // Extended configuration
    /// Optional address lookup table for transaction size optimization
    pub address_lookup_table_account: Option<AddressLookupTableAccount>,
    /// Whether to wait for transaction confirmation before returning
    pub wait_tx_confirmed: bool,
    /// Whether to create input token associated token account
    pub create_input_token_ata: bool,
    /// Whether to close input token associated token account after trade
    pub close_input_token_ata: bool,
    /// Whether to create token mint associated token account
    pub create_mint_ata: bool,
    /// Durable nonce information
    pub durable_nonce: Option<DurableNonceInfo>,
    /// Optional fixed output token amount (If this value is set, it will be directly assigned to the output amount instead of being calculated)
    pub fixed_output_token_amount: Option<u64>,
    /// Gas fee strategy
    pub gas_fee_strategy: GasFeeStrategy,
    /// Whether to simulate the transaction instead of executing it
    pub simulate: bool,
    /// Use exact SOL amount instructions (buy_exact_sol_in for PumpFun, buy_exact_quote_in for PumpSwap).
    /// When Some(true) or None (default), the exact SOL/quote amount is spent and slippage is applied to output tokens.
    /// When Some(false), uses regular buy instruction where slippage is applied to SOL/quote input.
    /// This option only applies to PumpFun and PumpSwap DEXes; it is ignored for other DEXes.
    pub use_exact_sol_amount: Option<bool>,
    /// 可选：事件收到时间（微秒，与 sol-parser-sdk 的 metadata.grpc_recv_us / clock::now_micros 同源）。不传且开启 log_enabled 时 SDK 用 now_micros() 作为起点，打印起点→提交耗时。
    pub grpc_recv_us: Option<i64>,
}

/// Parameters for executing sell orders across different DEX protocols
///
/// Contains all necessary configuration for selling tokens, including
/// protocol-specific settings, tip preferences, account management options, and transaction preferences.
#[derive(Clone)]
pub struct TradeSellParams {
    // Trading configuration
    /// The DEX protocol to use for the trade
    pub dex_type: DexType,
    /// Type of the token to sell
    pub output_token_type: TradeTokenType,
    /// Public key of the token to sell
    pub mint: Pubkey,
    /// Amount of tokens to sell (in smallest token units)
    pub input_token_amount: u64,
    /// Optional slippage tolerance in basis points (e.g., 100 = 1%)
    pub slippage_basis_points: Option<u64>,
    /// Recent blockhash for transaction validity
    pub recent_blockhash: Option<Hash>,
    /// Whether to include tip for transaction priority
    pub with_tip: bool,
    /// Protocol-specific parameters (PumpFun, Raydium, etc.)
    pub extension_params: DexParamEnum,
    // Extended configuration
    /// Optional address lookup table for transaction size optimization
    pub address_lookup_table_account: Option<AddressLookupTableAccount>,
    /// Whether to wait for transaction confirmation before returning
    pub wait_tx_confirmed: bool,
    /// Whether to create output token associated token account
    pub create_output_token_ata: bool,
    /// Whether to close output token associated token account after trade
    pub close_output_token_ata: bool,
    /// Whether to close mint token associated token account after trade
    pub close_mint_token_ata: bool,
    /// Durable nonce information
    pub durable_nonce: Option<DurableNonceInfo>,
    /// Optional fixed output token amount (If this value is set, it will be directly assigned to the output amount instead of being calculated)
    pub fixed_output_token_amount: Option<u64>,
    /// Gas fee strategy
    pub gas_fee_strategy: GasFeeStrategy,
    /// Whether to simulate the transaction instead of executing it
    pub simulate: bool,
    /// 可选：事件收到时间（微秒，与 sol-parser-sdk clock 同源）。不传且开启 log_enabled 时 SDK 用 now_micros() 作为起点。
    pub grpc_recv_us: Option<i64>,
}

impl TradingClient {
    /// Create a TradingClient from shared infrastructure (fast path)
    ///
    /// This is the preferred method when multiple wallets share the same infrastructure.
    /// It only performs wallet-specific initialization (fast_init) without the expensive
    /// RPC/SWQOS client creation.
    ///
    /// # Arguments
    /// * `payer` - The keypair used for signing transactions
    /// * `infrastructure` - Shared infrastructure (RPC client, SWQOS clients)
    /// * `use_seed_optimize` - Whether to use seed optimization for ATA operations
    ///
    /// # Returns
    /// Returns a configured `TradingClient` instance ready for trading operations
    pub fn from_infrastructure(
        payer: Arc<Keypair>,
        infrastructure: Arc<TradingInfrastructure>,
        use_seed_optimize: bool,
    ) -> Self {
        // Initialize wallet-specific caches (fast, synchronous)
        crate::common::fast_fn::fast_init(&payer.pubkey());
        let max_sender_concurrency = infrastructure.max_sender_concurrency;
        let effective_core_ids = infrastructure.effective_core_ids.clone();

        Self {
            payer,
            infrastructure,
            middleware_manager: None,
            use_seed_optimize,
            use_dedicated_sender_threads: false,
            sender_thread_cores: None,
            max_sender_concurrency,
            effective_core_ids,
            log_enabled: true,
            check_min_tip: false,
        }
    }

    /// Create a TradingClient from shared infrastructure with optional WSOL ATA setup
    ///
    /// Same as `from_infrastructure` but also handles WSOL ATA creation if requested.
    ///
    /// # Arguments
    /// * `payer` - The keypair used for signing transactions
    /// * `infrastructure` - Shared infrastructure (RPC client, SWQOS clients)
    /// * `use_seed_optimize` - Whether to use seed optimization for ATA operations
    /// * `create_wsol_ata` - Whether to check/create WSOL ATA
    pub async fn from_infrastructure_with_wsol_setup(
        payer: Arc<Keypair>,
        infrastructure: Arc<TradingInfrastructure>,
        use_seed_optimize: bool,
        create_wsol_ata: bool,
    ) -> Self {
        crate::common::fast_fn::fast_init(&payer.pubkey());

        if create_wsol_ata {
            // 在后台异步创建 WSOL ATA，不阻塞启动
            let payer_clone = payer.clone();
            let rpc_clone = infrastructure.rpc.clone();
            tokio::spawn(async move {
                Self::ensure_wsol_ata(&payer_clone, &rpc_clone).await;
            });
            if sdk_log::sdk_log_enabled() {
                info!(target: "sol_trade_sdk", "ℹ️ WSOL ATA creation started in background, does not block bot startup");
            }
        }

        let max_sender_concurrency = infrastructure.max_sender_concurrency;
        let effective_core_ids = infrastructure.effective_core_ids.clone();

        Self {
            payer,
            infrastructure,
            middleware_manager: None,
            use_seed_optimize,
            use_dedicated_sender_threads: false,
            sender_thread_cores: None,
            max_sender_concurrency,
            effective_core_ids,
            log_enabled: true,
            check_min_tip: false,
        }
    }

    /// 单次尝试创建 WSOL ATA：获取 blockhash、组交易、发送并确认。成功或账户已存在返回 Ok(())，否则返回 Err(错误信息)。
    async fn try_create_wsol_ata_once(
        rpc: &SolanaRpcClient,
        payer: &Arc<Keypair>,
        wsol_ata: &solana_sdk::pubkey::Pubkey,
        create_ata_ixs: &[solana_sdk::instruction::Instruction],
        timeout_secs: u64,
    ) -> Result<(), String> {
        use solana_sdk::transaction::Transaction;
        let recent_blockhash = rpc
            .get_latest_blockhash()
            .await
            .map_err(|e| format!("Failed to get blockhash: {}", e))?;
        let tx = Transaction::new_signed_with_payer(
            create_ata_ixs,
            Some(&payer.pubkey()),
            &[payer.as_ref()],
            recent_blockhash,
        );
        let send_result = tokio::time::timeout(
            tokio::time::Duration::from_secs(timeout_secs),
            rpc.send_and_confirm_transaction(&tx),
        )
        .await;
        match send_result {
            Ok(Ok(_signature)) => Ok(()),
            Ok(Err(e)) => {
                if rpc.get_account(wsol_ata).await.is_ok() {
                    return Ok(());
                }
                Err(format!("{}", e))
            }
            Err(_) => Err(format!("Transaction confirmation timeout ({}s)", timeout_secs)),
        }
    }

    /// 确保钱包存在 WSOL ATA；不存在则发交易创建（会花费租金 + 手续费，初始化阶段唯一会扣钱的逻辑）
    async fn ensure_wsol_ata(payer: &Arc<Keypair>, rpc: &Arc<SolanaRpcClient>) {
        const MAX_RETRIES: usize = 3;
        const TIMEOUT_SECS: u64 = 10;

        let wsol_ata = crate::common::fast_fn::get_associated_token_address_with_program_id_fast(
            &payer.pubkey(),
            &WSOL_TOKEN_ACCOUNT,
            &crate::constants::TOKEN_PROGRAM,
        );

        if rpc.get_account(&wsol_ata).await.is_ok() {
            if sdk_log::sdk_log_enabled() {
                info!(target: "sol_trade_sdk", "✅ WSOL ATA already exists: {}", wsol_ata);
            }
            return;
        }

        let create_ata_ixs = crate::trading::common::wsol_manager::create_wsol_ata(&payer.pubkey());
        if create_ata_ixs.is_empty() {
            if sdk_log::sdk_log_enabled() {
                info!(target: "sol_trade_sdk", "ℹ️ WSOL ATA already exists (no need to create)");
            }
            return;
        }

        if sdk_log::sdk_log_enabled() {
            info!(target: "sol_trade_sdk", "🔨 Creating WSOL ATA: {}", wsol_ata);
        }
        let mut last_error = None;
        for attempt in 1..=MAX_RETRIES {
            if attempt > 1 {
                if sdk_log::sdk_log_enabled() {
                    info!(target: "sol_trade_sdk", "🔄 Retrying WSOL ATA creation (attempt {}/{})...", attempt, MAX_RETRIES);
                }
                tokio::time::sleep(tokio::time::Duration::from_secs(2)).await;
            }
            match Self::try_create_wsol_ata_once(
                rpc.as_ref(),
                payer,
                &wsol_ata,
                &create_ata_ixs,
                TIMEOUT_SECS,
            )
            .await
            {
                Ok(()) => {
                    if sdk_log::sdk_log_enabled() {
                        info!(target: "sol_trade_sdk", "✅ WSOL ATA created or already exists");
                    }
                    return;
                }
                Err(e) => {
                    last_error = Some(e.clone());
                    if attempt < MAX_RETRIES && sdk_log::sdk_log_enabled() {
                        warn!(target: "sol_trade_sdk", "⚠️ Attempt {} failed: {}", attempt, e);
                    }
                }
            }
        }

        if let Some(err) = last_error {
            if sdk_log::sdk_log_enabled() {
                error!(target: "sol_trade_sdk", "❌ WSOL ATA creation failed after {} retries: {}", MAX_RETRIES, wsol_ata);
                error!(target: "sol_trade_sdk", "   Error: {}", err);
                error!(target: "sol_trade_sdk", "   💡 Possible causes: insufficient SOL, RPC timeout, or fee");
                error!(target: "sol_trade_sdk", "   🔧 Solutions: fund wallet (e.g. 0.1 SOL), retry, check RPC");
            }
            std::thread::sleep(std::time::Duration::from_secs(5));
            panic!(
                "❌ WSOL ATA creation failed and account does not exist: {}. Error: {}",
                wsol_ata, err
            );
        }
    }

    /// Creates a new SolTradingSDK instance with the specified configuration
    ///
    /// This function initializes the trading system with RPC connection, SWQOS settings,
    /// and sets up necessary components for trading operations.
    ///
    /// # Arguments
    /// * `payer` - The keypair used for signing transactions
    /// * `trade_config` - Trading configuration including RPC URL, SWQOS settings, etc.
    ///
    /// # Returns
    /// Returns a configured `SolTradingSDK` instance ready for trading operations
    #[inline]
    pub async fn new(payer: Arc<Keypair>, trade_config: TradeConfig) -> Self {
        // 设置 SDK 全局日志开关，后续所有 SDK 内日志（SWQOS/WSOL/耗时等）均受此控制
        sdk_log::set_sdk_log_enabled(trade_config.log_enabled);
        // 预热高性能时钟，避免首笔交易时触发 3 次 Utc::now() 校准
        let _ = crate::common::clock::now_micros();
        // Create infrastructure from trade config
        let infra_config = InfrastructureConfig::from_trade_config(&trade_config);
        let infrastructure = Arc::new(TradingInfrastructure::new(infra_config).await);

        // Initialize wallet-specific caches
        crate::common::fast_fn::fast_init(&payer.pubkey());

        // ═══════════════════════════════════════════════════════════════════════════════
        // 初始化阶段会花费租金/手续费的唯一路径：创建 WSOL ATA（ensure_wsol_ata）
        // - 触发条件：create_wsol_ata_on_startup == true 且钱包 SOL >= MIN_SOL_FOR_WSOL_ATA_LAMPORTS
        // - 花费：ATA 租金（约 0.00203928 SOL）+ 交易手续费；钱包不足时已跳过
        // - 其它初始化（TradingInfrastructure::new、update_rents、get_swqos_client）仅 RPC/HTTP，不发送交易
        // ═══════════════════════════════════════════════════════════════════════════════
        if trade_config.create_wsol_ata_on_startup {
            const MIN_SOL_FOR_WSOL_ATA_LAMPORTS: u64 = 500_000; // 约 0.0005 SOL，用于 ATA 租金 + 手续费
            const BALANCE_CHECK_TIMEOUT: std::time::Duration = std::time::Duration::from_secs(5);
            let balance = tokio::time::timeout(
                BALANCE_CHECK_TIMEOUT,
                infrastructure.rpc.get_balance(&payer.pubkey()),
            )
            .await
            .unwrap_or(Ok(0))
            .unwrap_or(0);
            if balance >= MIN_SOL_FOR_WSOL_ATA_LAMPORTS {
                Self::ensure_wsol_ata(&payer, &infrastructure.rpc).await;
            } else if sdk_log::sdk_log_enabled() {
                info!(
                    target: "sol_trade_sdk",
                    "⏭️ 跳过创建 WSOL ATA：钱包 SOL 不足（当前 {} lamports，需要至少 {}）",
                    balance,
                    MIN_SOL_FOR_WSOL_ATA_LAMPORTS
                );
            }
        }

        // 并发/核心相关由 infrastructure 预计算，用户无需配置
        let instance = Self {
            payer,
            infrastructure: infrastructure.clone(),
            middleware_manager: None,
            use_seed_optimize: trade_config.use_seed_optimize,
            use_dedicated_sender_threads: false,
            sender_thread_cores: None,
            max_sender_concurrency: infrastructure.max_sender_concurrency,
            effective_core_ids: infrastructure.effective_core_ids.clone(),
            log_enabled: trade_config.log_enabled,
            check_min_tip: trade_config.check_min_tip,
        };

        let mut current = INSTANCE.lock();
        *current = Some(Arc::new(instance.clone()));

        instance
    }

    /// Adds a middleware manager to the SolanaTrade instance
    ///
    /// Middleware managers can be used to implement custom logic that runs before or after trading operations,
    /// such as logging, monitoring, or custom validation.
    ///
    /// # Arguments
    /// * `middleware_manager` - The middleware manager to attach
    ///
    /// # Returns
    /// Returns the modified SolanaTrade instance with middleware manager attached
    pub fn with_middleware_manager(mut self, middleware_manager: MiddlewareManager) -> Self {
        self.middleware_manager = Some(Arc::new(middleware_manager));
        self
    }

    /// **Advanced.** Use dedicated OS threads for sender pool (and optionally pin to cores).  
    /// By default the SDK uses a shared tokio pool; this can reduce scheduling contention when sending many txs.  
    /// Concurrency and core count are capped internally (≤ swqos count, ≤ 2/3 of CPU cores).  
    /// - `None`: keep default (shared tokio pool).  
    /// - `Some(vec![])`: dedicated threads with default count, no core pinning.  
    /// - `Some(indices)`: dedicated threads pinned to those core indices (trimmed to cap).  
    ///  
    /// **Latency note:** If a core is busy with other work (node, bot), SWQOS submit on that core can be delayed.  
    /// For lowest latency, pass core indices that are *reserved* for SWQOS (do not run other CPU-heavy work on those cores).
    pub fn with_dedicated_sender_threads(mut self, core_indices: Option<Vec<usize>>) -> Self {
        match core_indices {
            None => {
                self.use_dedicated_sender_threads = false;
                self.sender_thread_cores = None;
            }
            Some(v) if v.is_empty() => {
                self.use_dedicated_sender_threads = true;
                self.sender_thread_cores = None;
            }
            Some(v) => {
                self.use_dedicated_sender_threads = true;
                let cap = v.len().min(self.max_sender_concurrency);
                self.sender_thread_cores = Some(Arc::new(if cap < v.len() { v[..cap].to_vec() } else { v }));
            }
        }
        self
    }

    /// Gets the RPC client instance for direct Solana blockchain interactions
    ///
    /// This provides access to the underlying Solana RPC client that can be used
    /// for custom blockchain operations outside of the trading framework.
    ///
    /// # Returns
    /// Returns a reference to the Arc-wrapped SolanaRpcClient instance
    pub fn get_rpc(&self) -> &Arc<SolanaRpcClient> {
        &self.infrastructure.rpc
    }

    /// Gets the current globally shared SolanaTrade instance
    ///
    /// This provides access to the singleton instance that was created with `new()`.
    /// Useful for accessing the trading instance from different parts of the application.
    ///
    /// # Returns
    /// Returns the Arc-wrapped SolanaTrade instance
    ///
    /// # Panics
    /// Panics if no instance has been initialized yet. Make sure to call `new()` first.
    pub fn get_instance() -> Arc<Self> {
        let instance = INSTANCE.lock();
        instance
            .as_ref()
            .expect("SolanaTrade instance not initialized. Please call new() first.")
            .clone()
    }

    /// Execute a buy order for a specified token
    ///
    /// 🔧 修复：返回Vec<Signature>支持多SWQOS并发交易
    /// - bool: 是否至少有一个交易成功
    /// - Vec<Signature>: 所有提交的交易签名（按SWQOS顺序）
    /// - Option<TradeError>: 最后一个错误（如果全部失败）
    ///
    /// # Arguments
    ///
    /// * `params` - Buy trade parameters containing all necessary trading configuration
    ///
    /// # Returns
    ///
    /// Returns `Ok((bool, Vec<Signature>, Option<TradeError>))` with success flag and all transaction signatures,
    /// or an error if the transaction fails.
    ///
    /// # Errors
    ///
    /// This function will return an error if:
    /// - Invalid protocol parameters are provided for the specified DEX type
    /// - The transaction fails to execute
    /// - Network or RPC errors occur
    /// - Insufficient SOL balance for the purchase
    /// - Required accounts cannot be created or accessed
    #[inline]
    pub async fn buy(
        &self,
        params: TradeBuyParams,
    ) -> Result<(bool, Vec<Signature>, Option<TradeError>, Vec<(crate::swqos::SwqosType, i64)>), anyhow::Error> {
        if params.recent_blockhash.is_none() && params.durable_nonce.is_none() {
            return Err(anyhow::anyhow!(
                "Must provide either recent_blockhash or durable_nonce for buy (required for transaction validity)"
            ));
        }
        #[cfg(feature = "perf-trace")]
        if sdk_log::sdk_log_enabled() && params.slippage_basis_points.is_none() {
            debug!(
                target: "sol_trade_sdk",
                "slippage_basis_points is none, use default slippage basis points: {}",
                DEFAULT_SLIPPAGE
            );
        }
        if params.input_token_type == TradeTokenType::USD1 && params.dex_type != DexType::Bonk {
            return Err(anyhow::anyhow!(
                " Current version only supports USD1 trading on Bonk protocols"
            ));
        }
        let protocol_params = params.extension_params;
        if !validate_protocol_params(params.dex_type, &protocol_params) {
            return Err(anyhow::anyhow!(
                "Invalid protocol params for Trade (dex={:?})",
                params.dex_type
            ));
        }
        let input_token_mint = if params.input_token_type == TradeTokenType::SOL {
            SOL_TOKEN_ACCOUNT
        } else if params.input_token_type == TradeTokenType::WSOL {
            WSOL_TOKEN_ACCOUNT
        } else if params.input_token_type == TradeTokenType::USDC {
            USDC_TOKEN_ACCOUNT
        } else {
            USD1_TOKEN_ACCOUNT
        };
        let executor = TradeFactory::create_executor(params.dex_type);
        let buy_params = SwapParams {
            rpc: Some(self.infrastructure.rpc.clone()),
            payer: self.payer.clone(),
            trade_type: TradeType::Buy,
            input_mint: input_token_mint,
            output_mint: params.mint,
            input_token_program: None,
            output_token_program: None,
            input_amount: Some(params.input_token_amount),
            slippage_basis_points: params.slippage_basis_points,
            address_lookup_table_account: params.address_lookup_table_account,
            recent_blockhash: params.recent_blockhash,
            wait_tx_confirmed: params.wait_tx_confirmed,
            protocol_params,
            open_seed_optimize: self.use_seed_optimize, // 使用全局seed优化配置
            swqos_clients: self.infrastructure.swqos_clients.clone(),
            middleware_manager: self.middleware_manager.clone(),
            durable_nonce: params.durable_nonce,
            with_tip: true,
            create_input_mint_ata: params.create_input_token_ata,
            close_input_mint_ata: params.close_input_token_ata,
            create_output_mint_ata: params.create_mint_ata,
            close_output_mint_ata: false,
            fixed_output_amount: params.fixed_output_token_amount,
            gas_fee_strategy: params.gas_fee_strategy,
            simulate: params.simulate,
            log_enabled: self.log_enabled,
            use_dedicated_sender_threads: self.use_dedicated_sender_threads,
            sender_thread_cores: self.sender_thread_cores.clone(),
            max_sender_concurrency: self.max_sender_concurrency,
            effective_core_ids: self.effective_core_ids.clone(),
            check_min_tip: self.check_min_tip,
            grpc_recv_us: params.grpc_recv_us,
            use_exact_sol_amount: params.use_exact_sol_amount,
        };

        let swap_result = executor.swap(buy_params).await;
        let result =
            swap_result.map(|(success, sigs, err, timings)| (success, sigs, err.map(TradeError::from), timings));
        result
    }

    /// Execute a sell order for a specified token
    ///
    /// 🔧 修复：返回Vec<Signature>支持多SWQOS并发交易
    /// - bool: 是否至少有一个交易成功
    /// - Vec<Signature>: 所有提交的交易签名（按SWQOS顺序）
    /// - Option<TradeError>: 最后一个错误（如果全部失败）
    ///
    /// # Arguments
    ///
    /// * `params` - Sell trade parameters containing all necessary trading configuration
    ///
    /// # Returns
    ///
    /// Returns `Ok((bool, Vec<Signature>, Option<TradeError>))` with success flag and all transaction signatures,
    /// or an error if the transaction fails.
    ///
    /// # Errors
    ///
    /// This function will return an error if:
    /// - Invalid protocol parameters are provided for the specified DEX type
    /// - The transaction fails to execute
    /// - Network or RPC errors occur
    /// - Insufficient token balance for the sale
    /// - Token account doesn't exist or is not properly initialized
    /// - Required accounts cannot be created or accessed
    #[inline]
    pub async fn sell(
        &self,
        params: TradeSellParams,
    ) -> Result<(bool, Vec<Signature>, Option<TradeError>, Vec<(crate::swqos::SwqosType, i64)>), anyhow::Error> {
        #[cfg(feature = "perf-trace")]
        if sdk_log::sdk_log_enabled() && params.slippage_basis_points.is_none() {
            debug!(
                target: "sol_trade_sdk",
                "slippage_basis_points is none, use default slippage basis points: {}",
                DEFAULT_SLIPPAGE
            );
        }
        if params.recent_blockhash.is_none() && params.durable_nonce.is_none() {
            return Err(anyhow::anyhow!(
                "Must provide either recent_blockhash or durable_nonce for sell (required for transaction validity)"
            ));
        }
        if params.output_token_type == TradeTokenType::USD1 && params.dex_type != DexType::Bonk {
            return Err(anyhow::anyhow!(
                " Current version only supports USD1 trading on Bonk protocols"
            ));
        }
        let protocol_params = params.extension_params;
        if !validate_protocol_params(params.dex_type, &protocol_params) {
            return Err(anyhow::anyhow!(
                "Invalid protocol params for Trade (dex={:?})",
                params.dex_type
            ));
        }
        let executor = TradeFactory::create_executor(params.dex_type);
        let output_token_mint = if params.output_token_type == TradeTokenType::SOL {
            SOL_TOKEN_ACCOUNT
        } else if params.output_token_type == TradeTokenType::WSOL {
            WSOL_TOKEN_ACCOUNT
        } else if params.output_token_type == TradeTokenType::USDC {
            USDC_TOKEN_ACCOUNT
        } else {
            USD1_TOKEN_ACCOUNT
        };
        let sell_params = SwapParams {
            rpc: Some(self.infrastructure.rpc.clone()),
            payer: self.payer.clone(),
            trade_type: TradeType::Sell,
            input_mint: params.mint,
            output_mint: output_token_mint,
            input_token_program: None,
            output_token_program: None,
            input_amount: Some(params.input_token_amount),
            slippage_basis_points: params.slippage_basis_points,
            address_lookup_table_account: params.address_lookup_table_account,
            recent_blockhash: params.recent_blockhash,
            wait_tx_confirmed: params.wait_tx_confirmed,
            protocol_params,
            with_tip: params.with_tip,
            open_seed_optimize: self.use_seed_optimize, // 使用全局seed优化配置
            swqos_clients: self.infrastructure.swqos_clients.clone(),
            middleware_manager: self.middleware_manager.clone(),
            durable_nonce: params.durable_nonce,
            create_input_mint_ata: false,
            close_input_mint_ata: params.close_mint_token_ata,
            create_output_mint_ata: params.create_output_token_ata,
            close_output_mint_ata: params.close_output_token_ata,
            fixed_output_amount: params.fixed_output_token_amount,
            gas_fee_strategy: params.gas_fee_strategy,
            simulate: params.simulate,
            log_enabled: self.log_enabled,
            use_dedicated_sender_threads: self.use_dedicated_sender_threads,
            sender_thread_cores: self.sender_thread_cores.clone(),
            max_sender_concurrency: self.max_sender_concurrency,
            effective_core_ids: self.effective_core_ids.clone(),
            check_min_tip: self.check_min_tip,
            grpc_recv_us: params.grpc_recv_us,
            use_exact_sol_amount: None,
        };

        let swap_result = executor.swap(sell_params).await;
        let result =
            swap_result.map(|(success, sigs, err, timings)| (success, sigs, err.map(TradeError::from), timings));
        result
    }

    /// Execute a sell order for a percentage of the specified token amount
    ///
    /// This is a convenience function that calculates the exact amount to sell based on
    /// a percentage of the total token amount and then calls the `sell` function.
    ///
    /// # Arguments
    ///
    /// * `params` - Sell trade parameters (will be modified with calculated token amount)
    /// * `amount_token` - Total amount of tokens available (in smallest token units)
    /// * `percent` - Percentage of tokens to sell (1-100, where 100 = 100%)
    ///
    /// # Returns
    ///
    /// Returns `Ok(Signature)` with the transaction signature if the sell order is successfully executed,
    /// or an error if the transaction fails.
    ///
    /// # Errors
    ///
    /// This function will return an error if:
    /// - `percent` is 0 or greater than 100
    /// - Invalid protocol parameters are provided for the specified DEX type
    /// - The transaction fails to execute
    /// - Network or RPC errors occur
    /// - Insufficient token balance for the calculated sale amount
    /// - Token account doesn't exist or is not properly initialized
    /// - Required accounts cannot be created or accessed
    pub async fn sell_by_percent(
        &self,
        mut params: TradeSellParams,
        amount_token: u64,
        percent: u64,
    ) -> Result<(bool, Vec<Signature>, Option<TradeError>, Vec<(crate::swqos::SwqosType, i64)>), anyhow::Error> {
        if percent == 0 || percent > 100 {
            return Err(anyhow::anyhow!("Percentage must be between 1 and 100"));
        }
        let amount = amount_token * percent / 100;
        params.input_token_amount = amount;
        self.sell(params).await
    }

    /// Wraps native SOL into wSOL (Wrapped SOL) for use in SPL token operations
    ///
    /// This function creates a wSOL associated token account (if it doesn't exist),
    /// transfers the specified amount of SOL to that account, and then syncs the native
    /// token balance to make SOL usable as an SPL token in trading operations.
    ///
    /// # Arguments
    /// * `amount` - The amount of SOL to wrap (in lamports)
    ///
    /// # Returns
    /// * `Ok(String)` - Transaction signature if successful
    /// * `Err(anyhow::Error)` - If the transaction fails to execute
    ///
    /// # Errors
    ///
    /// This function will return an error if:
    /// - Insufficient SOL balance for the wrap operation
    /// - wSOL associated token account creation fails
    /// - Transaction fails to execute or confirm
    /// - Network or RPC errors occur
    pub async fn wrap_sol_to_wsol(&self, amount: u64) -> Result<String, anyhow::Error> {
        use crate::trading::common::wsol_manager::handle_wsol;
        use solana_sdk::transaction::Transaction;
        let recent_blockhash = self.infrastructure.rpc.get_latest_blockhash().await?;
        let instructions = handle_wsol(&self.payer.pubkey(), amount);
        let mut transaction =
            Transaction::new_with_payer(&instructions, Some(&self.payer.pubkey()));
        transaction.sign(&[&*self.payer], recent_blockhash);
        let signature = self.infrastructure.rpc.send_and_confirm_transaction(&transaction).await?;
        Ok(signature.to_string())
    }
    /// Closes the wSOL associated token account and unwraps remaining balance to native SOL
    ///
    /// This function closes the wSOL associated token account, which automatically
    /// transfers any remaining wSOL balance back to the account owner as native SOL.
    /// This is useful for cleaning up wSOL accounts and recovering wrapped SOL after trading operations.
    ///
    /// # Returns
    /// * `Ok(String)` - Transaction signature if successful
    /// * `Err(anyhow::Error)` - If the transaction fails to execute
    ///
    /// # Errors
    ///
    /// This function will return an error if:
    /// - wSOL associated token account doesn't exist
    /// - Account closure fails due to insufficient permissions
    /// - Transaction fails to execute or confirm
    /// - Network or RPC errors occur
    pub async fn close_wsol(&self) -> Result<String, anyhow::Error> {
        use crate::trading::common::wsol_manager::close_wsol;
        use solana_sdk::transaction::Transaction;
        let recent_blockhash = self.infrastructure.rpc.get_latest_blockhash().await?;
        let instructions = close_wsol(&self.payer.pubkey());
        let mut transaction =
            Transaction::new_with_payer(&instructions, Some(&self.payer.pubkey()));
        transaction.sign(&[&*self.payer], recent_blockhash);
        let signature = self.infrastructure.rpc.send_and_confirm_transaction(&transaction).await?;
        Ok(signature.to_string())
    }

    /// Creates a wSOL associated token account (ATA) without wrapping any SOL
    ///
    /// This function only creates the wSOL associated token account for the payer
    /// without transferring any SOL into it. This is useful when you want to set up
    /// the account infrastructure in advance without committing funds yet.
    ///
    /// # Returns
    /// * `Ok(String)` - Transaction signature if successful
    /// * `Err(anyhow::Error)` - If the transaction fails to execute
    ///
    /// # Errors
    ///
    /// This function will return an error if:
    /// - wSOL ATA account already exists (idempotent, will succeed silently)
    /// - Transaction fails to execute or confirm
    /// - Network or RPC errors occur
    /// - Insufficient SOL for transaction fees
    pub async fn create_wsol_ata(&self) -> Result<String, anyhow::Error> {
        use crate::trading::common::wsol_manager::create_wsol_ata;
        use solana_sdk::transaction::Transaction;

        let recent_blockhash = self.infrastructure.rpc.get_latest_blockhash().await?;
        let instructions = create_wsol_ata(&self.payer.pubkey());

        // If instructions are empty, ATA already exists
        if instructions.is_empty() {
            return Err(anyhow::anyhow!("wSOL ATA already exists or no instructions needed"));
        }

        let mut transaction =
            Transaction::new_with_payer(&instructions, Some(&self.payer.pubkey()));
        transaction.sign(&[&*self.payer], recent_blockhash);
        let signature = self.infrastructure.rpc.send_and_confirm_transaction(&transaction).await?;
        Ok(signature.to_string())
    }

    /// 将 WSOL 转换为 SOL，使用 seed 账户
    ///
    /// 这个函数实现以下步骤：
    /// 1. 使用 super::seed::create_associated_token_account_use_seed 创建 WSOL seed 账号
    /// 2. 使用 get_associated_token_address_with_program_id_use_seed 获取该账号的 ATA 地址
    /// 3. 添加从用户 WSOL ATA 转账到该 seed ATA 账号的指令
    /// 4. 添加关闭 WSOL seed 账号的指令
    ///
    /// # Arguments
    /// * `amount` - 要转换的 WSOL 数量（以 lamports 为单位）
    ///
    /// # Returns
    /// * `Ok(String)` - 交易签名
    /// * `Err(anyhow::Error)` - 如果交易执行失败
    ///
    /// # Errors
    ///
    /// 此函数在以下情况下会返回错误：
    /// - 用户 WSOL ATA 中余额不足
    /// - seed 账户创建失败
    /// - 转账指令执行失败
    /// - 交易执行或确认失败
    /// - 网络或 RPC 错误
    pub async fn wrap_wsol_to_sol(&self, amount: u64) -> Result<String, anyhow::Error> {
        use crate::common::seed::get_associated_token_address_with_program_id_use_seed;
        use crate::trading::common::wsol_manager::{
            wrap_wsol_to_sol as wrap_wsol_to_sol_internal, wrap_wsol_to_sol_without_create,
        };
        use solana_sdk::transaction::Transaction;

        // 检查临时seed账户是否已存在
        let seed_ata_address = get_associated_token_address_with_program_id_use_seed(
            &self.payer.pubkey(),
            &crate::constants::WSOL_TOKEN_ACCOUNT,
            &crate::constants::TOKEN_PROGRAM,
        )?;

        let account_exists = self.infrastructure.rpc.get_account(&seed_ata_address).await.is_ok();

        let instructions = if account_exists {
            // 如果账户已存在，使用不创建账户的版本
            wrap_wsol_to_sol_without_create(&self.payer.pubkey(), amount)?
        } else {
            // 如果账户不存在，使用创建账户的版本
            wrap_wsol_to_sol_internal(&self.payer.pubkey(), amount)?
        };

        let recent_blockhash = self.infrastructure.rpc.get_latest_blockhash().await?;
        let mut transaction =
            Transaction::new_with_payer(&instructions, Some(&self.payer.pubkey()));
        transaction.sign(&[&*self.payer], recent_blockhash);
        let signature = self.infrastructure.rpc.send_and_confirm_transaction(&transaction).await?;
        Ok(signature.to_string())
    }

    /// Claim Bonding Curve (Pump) cashback.
    ///
    /// Transfers native SOL from the user's UserVolumeAccumulator to the wallet.
    /// If there is nothing to claim, the transaction may still succeed with no SOL transferred.
    ///
    /// # Returns
    /// * `Ok(String)` - Transaction signature
    /// * `Err(anyhow::Error)` - Build or send failure (e.g. invalid PDA)
    pub async fn claim_cashback_pumpfun(&self) -> Result<String, anyhow::Error> {
        use solana_sdk::transaction::Transaction;
        let ix = crate::instruction::pumpfun::claim_cashback_pumpfun_instruction(
            &self.payer.pubkey(),
        )
        .ok_or_else(|| anyhow::anyhow!("Failed to build PumpFun claim_cashback instruction"))?;
        let recent_blockhash = self.infrastructure.rpc.get_latest_blockhash().await?;
        let mut transaction = Transaction::new_with_payer(&[ix], Some(&self.payer.pubkey()));
        transaction.sign(&[&*self.payer], recent_blockhash);
        let signature = self.infrastructure.rpc.send_and_confirm_transaction(&transaction).await?;
        Ok(signature.to_string())
    }

    /// Claim PumpSwap (AMM) cashback.
    ///
    /// Transfers WSOL from the UserVolumeAccumulator to the user's WSOL ATA.
    /// Creates the user's WSOL ATA idempotently if it does not exist, then claims.
    ///
    /// # Returns
    /// * `Ok(String)` - Transaction signature
    /// * `Err(anyhow::Error)` - Build or send failure
    pub async fn claim_cashback_pumpswap(&self) -> Result<String, anyhow::Error> {
        use solana_sdk::transaction::Transaction;
        let mut instructions =
            crate::common::fast_fn::create_associated_token_account_idempotent_fast_use_seed(
                &self.payer.pubkey(),
                &self.payer.pubkey(),
                &WSOL_TOKEN_ACCOUNT,
                &crate::constants::TOKEN_PROGRAM,
                self.use_seed_optimize,
            );
        let ix = crate::instruction::pumpswap::claim_cashback_pumpswap_instruction(
            &self.payer.pubkey(),
            WSOL_TOKEN_ACCOUNT,
            crate::constants::TOKEN_PROGRAM,
        )
        .ok_or_else(|| anyhow::anyhow!("Failed to build PumpSwap claim_cashback instruction"))?;
        instructions.push(ix);
        let recent_blockhash = self.infrastructure.rpc.get_latest_blockhash().await?;
        let mut transaction =
            Transaction::new_with_payer(&instructions, Some(&self.payer.pubkey()));
        transaction.sign(&[&*self.payer], recent_blockhash);
        let signature = self.infrastructure.rpc.send_and_confirm_transaction(&transaction).await?;
        Ok(signature.to_string())
    }
}