hyper/clp_hedger/uniswap_manager.py

import os
import time
import json
import re
from web3 import Web3
from eth_account import Account
from dotenv import load_dotenv

# --- Helper Functions ---
def clean_address(addr):
    return re.sub(r'[^0-9a-fA-FxX]', '', addr)

def price_from_sqrt_price_x96(sqrt_price_x96, token0_decimals, token1_decimals):
    price = (sqrt_price_x96 / (2**96))**2
    # Adjust for token decimals assuming price is Token1 per Token0
    price = price * (10**(token0_decimals - token1_decimals))
    return price

def price_from_tick(tick, token0_decimals, token1_decimals):
    price = 1.0001**tick
    # Adjust for token decimals assuming price is Token1 per Token0
    price = price * (10**(token0_decimals - token1_decimals))
    return price

def from_wei(amount, decimals):
    return amount / (10**decimals)

# --- V3 Math Helpers ---
def get_sqrt_ratio_at_tick(tick):
    # Returns sqrt(price) as a Q96 number
    return int((1.0001 ** (tick / 2)) * (2 ** 96))

def get_liquidity_for_amount0(sqrt_ratio_a, sqrt_ratio_b, amount0):
    # This function is not used directly in the current calculate_mint_amounts logic,
    # but is a common V3 helper
    if sqrt_ratio_a > sqrt_ratio_b:
        sqrt_ratio_a, sqrt_ratio_b = sqrt_ratio_b, sqrt_ratio_a
    # This formula is for a single-sided deposit when current price is outside the range
    return int(amount0 * sqrt_ratio_a * sqrt_ratio_b / (sqrt_ratio_b - sqrt_ratio_a))

def get_liquidity_for_amount1(sqrt_ratio_a, sqrt_ratio_b, amount1):
    # This function is not used directly in the current calculate_mint_amounts logic,
    # but is a common V3 helper
    if sqrt_ratio_a > sqrt_ratio_b:
        sqrt_ratio_a, sqrt_ratio_b = sqrt_ratio_b, sqrt_ratio_a
    # This formula is for a single-sided deposit when current price is outside the range
    return int(amount1 / (sqrt_ratio_b - sqrt_ratio_a))

def get_amounts_for_liquidity(sqrt_ratio_current, sqrt_ratio_a, sqrt_ratio_b, liquidity):
    # Calculates the required amount of token0 and token1 for a given liquidity and price range
    if sqrt_ratio_a > sqrt_ratio_b:
        sqrt_ratio_a, sqrt_ratio_b = sqrt_ratio_b, sqrt_ratio_a
        
    amount0 = 0
    amount1 = 0
    Q96 = 1 << 96 # 2^96
    
    # Current price below the lower tick boundary
    if sqrt_ratio_current <= sqrt_ratio_a:
        amount0 = ((liquidity * Q96) // sqrt_ratio_a) - ((liquidity * Q96) // sqrt_ratio_b)
        amount1 = 0
    # Current price within the range
    elif sqrt_ratio_current < sqrt_ratio_b:
        amount0 = ((liquidity * Q96) // sqrt_ratio_current) - ((liquidity * Q96) // sqrt_ratio_b)
        amount1 = (liquidity * (sqrt_ratio_current - sqrt_ratio_a)) // Q96
    # Current price above the upper tick boundary
    else:
        amount1 = (liquidity * (sqrt_ratio_b - sqrt_ratio_a)) // Q96
        amount0 = 0
        
    return amount0, amount1

# --- Configuration ---
# RPC URL and Private Key are loaded from .env
RPC_URL = os.environ.get("MAINNET_RPC_URL") 
PRIVATE_KEY = os.environ.get("MAIN_WALLET_PRIVATE_KEY") or os.environ.get("PRIVATE_KEY")

# Script behavior flags
MONITOR_INTERVAL_SECONDS = 451 
COLLECT_FEES_ENABLED = False # If True, will attempt to collect fees once and exit if no open auto position
CLOSE_POSITION_ENABLED = True # If True, will attempt to close auto position when out of range
CLOSE_IF_OUT_OF_RANGE_ONLY = True # If True, closes only if out of range; if False, closes immediately
OPEN_POSITION_ENABLED = True # If True, will open a new position if no auto position exists
REBALANCE_ON_CLOSE_BELOW_RANGE = False # If True, will sell 50% of WETH to USDC when closing below range

# New Position Parameters
TARGET_INVESTMENT_VALUE_TOKEN1 = 2000.0 # Target total investment value in Token1 terms (e.g. 350 USDC)
RANGE_WIDTH_PCT = 0.01 # +/- 2% range for new positions

# JSON File for tracking position state
STATUS_FILE = "hedge_status.json"

# --- JSON State Helpers ---
def get_active_automatic_position():
    """Reads hedge_status.json and returns the first OPEN AUTOMATIC position dict, or None."""
    if not os.path.exists(STATUS_FILE):
        return None
    try:
        with open(STATUS_FILE, 'r') as f:
            data = json.load(f)
            for entry in data:
                if entry.get('type') == 'AUTOMATIC' and entry.get('status') == 'OPEN':
                    return entry
    except Exception as e:
        print(f"ERROR reading status file: {e}")
    return None

def get_all_open_positions():
    """Reads hedge_status.json and returns a list of all OPEN positions (Manual and Automatic)."""
    if not os.path.exists(STATUS_FILE):
        return []
    try:
        with open(STATUS_FILE, 'r') as f:
            data = json.load(f)
            return [entry for entry in data if entry.get('status') == 'OPEN']
    except Exception as e:
        print(f"ERROR reading status file: {e}")
    return []

def update_hedge_status_file(action, position_data):
    """
    Updates the hedge_status.json file.
    action: "OPEN" or "CLOSE"
    position_data: Dict containing details (token_id, entry_price, range, etc.)
    """
    current_data = []
    if os.path.exists(STATUS_FILE):
        try:
            with open(STATUS_FILE, 'r') as f:
                current_data = json.load(f)
        except:
            current_data = []

    if action == "OPEN":
        # Format Timestamp
        open_ts = int(time.time())
        opened_str = time.strftime('%H:%M %d/%m/%y', time.localtime(open_ts))
        
        # Scale Amounts
        raw_amt0 = position_data.get('amount0_initial', 0)
        raw_amt1 = position_data.get('amount1_initial', 0)
        
        # Handle if they are already scaled (unlikely here, but safe)
        if raw_amt0 > 1000: fmt_amt0 = round(raw_amt0 / 10**18, 4)
        else: fmt_amt0 = round(raw_amt0, 4)
            
        if raw_amt1 > 1000: fmt_amt1 = round(raw_amt1 / 10**6, 2)
        else: fmt_amt1 = round(raw_amt1, 2)

        new_entry = {
            "type": "AUTOMATIC",
            "token_id": position_data['token_id'],
            "opened": opened_str,
            "status": "OPEN",
            "entry_price": round(position_data['entry_price'], 2),
            "target_value": round(position_data.get('target_value', 0.0), 2),
            "amount0_initial": fmt_amt0,
            "amount1_initial": fmt_amt1,
            
            "range_upper": round(position_data['range_upper'], 2),
            # Zones (if present in position_data, otherwise None/Skip)
            "zone_top_start_price": round(position_data['zone_top_start_price'], 2) if 'zone_top_start_price' in position_data else None,
            "zone_close_top_price": round(position_data['zone_close_end_price'], 2) if 'zone_close_end_price' in position_data else None,
            "zone_close_bottom_price": round(position_data['zone_close_start_price'], 2) if 'zone_close_start_price' in position_data else None,
            "zone_bottom_limit_price": round(position_data['zone_bottom_limit_price'], 2) if 'zone_bottom_limit_price' in position_data else None,
            "range_lower": round(position_data['range_lower'], 2),
            
            "static_long": 0.0,
            "timestamp_open": open_ts,
            "timestamp_close": None
        }
        # Remove None keys to keep it clean? Or keep structure?
        # User wants specific structure.
        
        current_data.append(new_entry)
        print(f"Recorded new AUTOMATIC position {position_data['token_id']} in {STATUS_FILE}")

    elif action == "CLOSE":
        found = False
        for entry in current_data:
            if (
                entry.get('type') == "AUTOMATIC" and 
                entry.get('status') == "OPEN" and 
                entry.get('token_id') == position_data['token_id']
            ):
                
                entry['status'] = "CLOSED"
                entry['timestamp_close'] = int(time.time())
                found = True
                print(f"Marked position {entry['token_id']} as CLOSED in {STATUS_FILE}")
                break
        if not found:
            print(f"WARNING: Could not find open AUTOMATIC position {position_data['token_id']} to close.")

    with open(STATUS_FILE, 'w') as f:
        json.dump(current_data, f, indent=2)

# --- ABIs ---
# Simplified for length, usually loaded from huge string
NONFUNGIBLE_POSITION_MANAGER_ABI = json.loads('''
[
    {"anonymous": false, "inputs": [{"indexed": true, "internalType": "uint256", "name": "tokenId", "type": "uint256"}, {"indexed": false, "internalType": "uint128", "name": "liquidity", "type": "uint128"}, {"indexed": false, "internalType": "uint256", "name": "amount0", "type": "uint256"}, {"indexed": false, "internalType": "uint256", "name": "amount1", "type": "uint256"}], "name": "IncreaseLiquidity", "type": "event"},
    {"anonymous": false, "inputs": [{"indexed": true, "internalType": "address", "name": "from", "type": "address"}, {"indexed": true, "internalType": "address", "name": "to", "type": "address"}, {"indexed": true, "internalType": "uint256", "name": "tokenId", "type": "uint256"}], "name": "Transfer", "type": "event"},
    {"inputs": [], "name": "factory", "outputs": [{"internalType": "address", "name": "", "type": "address"}], "stateMutability": "view", "type": "function"},
    {"inputs": [{"internalType": "uint256", "name": "tokenId", "type": "uint256"}], "name": "positions", "outputs": [{"internalType": "uint96", "name": "nonce", "type": "uint96"}, {"internalType": "address", "name": "operator", "type": "address"}, {"internalType": "address", "name": "token0", "type": "address"}, {"internalType": "address", "name": "token1", "type": "address"}, {"internalType": "uint24", "name": "fee", "type": "uint24"}, {"internalType": "int24", "name": "tickLower", "type": "int24"}, {"internalType": "int24", "name": "tickUpper", "type": "int24"}, {"internalType": "uint128", "name": "liquidity", "type": "uint128"}, {"internalType": "uint256", "name": "feeGrowthInside0LastX128", "type": "uint256"}, {"internalType": "uint256", "name": "feeGrowthInside1LastX128", "type": "uint256"}, {"internalType": "uint128", "name": "tokensOwed0", "type": "uint128"}, {"internalType": "uint128", "name": "tokensOwed1", "type": "uint128"}], "stateMutability": "view", "type": "function"},
    {"inputs": [{"components": [{"internalType": "uint256", "name": "tokenId", "type": "uint256"}, {"internalType": "address", "name": "recipient", "type": "address"}, {"internalType": "uint128", "name": "amount0Max", "type": "uint128"}, {"internalType": "uint128", "name": "amount1Max", "type": "uint128"}], "internalType": "struct INonfungiblePositionManager.CollectParams", "name": "params", "type": "tuple"}], "name": "collect", "outputs": [{"internalType": "uint256", "name": "amount0", "type": "uint256"}, {"internalType": "uint256", "name": "amount1", "type": "uint256"}], "stateMutability": "payable", "type": "function"},
    {"inputs": [{"components": [{"internalType": "uint256", "name": "tokenId", "type": "uint256"}, {"internalType": "uint128", "name": "liquidity", "type": "uint128"}, {"internalType": "uint256", "name": "amount0Min", "type": "uint256"}, {"internalType": "uint256", "name": "amount1Min", "type": "uint256"}, {"internalType": "uint256", "name": "deadline", "type": "uint256"}], "internalType": "struct INonfungiblePositionManager.DecreaseLiquidityParams", "name": "params", "type": "tuple"}], "name": "decreaseLiquidity", "outputs": [{"internalType": "uint256", "name": "amount0", "type": "uint256"}, {"internalType": "uint256", "name": "amount1", "type": "uint256"}], "stateMutability": "payable", "type": "function"},
    {"inputs": [{"components": [{"internalType": "address", "name": "token0", "type": "address"}, {"internalType": "address", "name": "token1", "type": "address"}, {"internalType": "uint24", "name": "fee", "type": "uint24"}, {"internalType": "int24", "name": "tickLower", "type": "int24"}, {"internalType": "int24", "name": "tickUpper", "type": "int24"}, {"internalType": "uint256", "name": "amount0Desired", "type": "uint256"}, {"internalType": "uint256", "name": "amount1Desired", "type": "uint256"}, {"internalType": "uint256", "name": "amount0Min", "type": "uint256"}, {"internalType": "uint256", "name": "amount1Min", "type": "uint256"}, {"internalType": "address", "name": "recipient", "type": "address"}, {"internalType": "uint256", "name": "deadline", "type": "uint256"}], "internalType": "struct INonfungiblePositionManager.MintParams", "name": "params", "type": "tuple"}], "name": "mint", "outputs": [{"internalType": "uint256", "name": "tokenId", "type": "uint256"}, {"internalType": "uint128", "name": "liquidity", "type": "uint128"}, {"internalType": "uint256", "name": "amount0", "type": "uint256"}, {"internalType": "uint256", "name": "amount1", "type": "uint256"}], "stateMutability": "payable", "type": "function"}
]
''')

UNISWAP_V3_POOL_ABI = json.loads('''
[
    {"inputs": [], "name": "slot0", "outputs": [{"internalType": "uint160", "name": "sqrtPriceX96", "type": "uint160"}, {"internalType": "int24", "name": "tick", "type": "int24"}, {"internalType": "uint16", "name": "observationIndex", "type": "uint16"}, {"internalType": "uint16", "name": "observationCardinality", "type": "uint16"}, {"internalType": "uint16", "name": "observationCardinalityNext", "type": "uint16"}, {"internalType": "uint8", "name": "feeProtocol", "type": "uint8"}, {"internalType": "bool", "name": "unlocked", "type": "bool"}], "stateMutability": "view", "type": "function"},
    {"inputs": [], "name": "token0", "outputs": [{"internalType": "address", "name": "", "type": "address"}], "stateMutability": "view", "type": "function"},
    {"inputs": [], "name": "token1", "outputs": [{"internalType": "address", "name": "", "type": "address"}], "stateMutability": "view", "type": "function"},
    {"inputs": [], "name": "fee", "outputs": [{"internalType": "uint24", "name": "", "type": "uint24"}], "stateMutability": "view", "type": "function"},
    {"inputs": [], "name": "liquidity", "outputs": [{"internalType": "uint128", "name": "", "type": "uint128"}], "stateMutability": "view", "type": "function"}
]
''')

ERC20_ABI = json.loads('''
[
    {"inputs": [], "name": "decimals", "outputs": [{"internalType": "uint8", "name": "", "type": "uint8"}], "stateMutability": "view", "type": "function"},
    {"inputs": [], "name": "symbol", "outputs": [{"internalType": "string", "name": "", "type": "string"}], "stateMutability": "view", "type": "function"},
    {"inputs": [{"internalType": "address", "name": "account", "type": "address"}], "name": "balanceOf", "outputs": [{"internalType": "uint256", "name": "", "type": "uint256"}], "stateMutability": "view", "type": "function"},
    {"inputs": [{"internalType": "address", "name": "spender", "type": "address"}, {"internalType": "uint256", "name": "amount", "type": "uint256"}], "name": "approve", "outputs": [{"internalType": "bool", "name": "", "type": "bool"}], "stateMutability": "nonpayable", "type": "function"},
    {"inputs": [{"internalType": "address", "name": "owner", "type": "address"}, {"internalType": "address", "name": "spender", "type": "address"}], "name": "allowance", "outputs": [{"internalType": "uint256", "name": "", "type": "uint256"}], "stateMutability": "view", "type": "function"}
]
''')

UNISWAP_V3_FACTORY_ABI = json.loads('''
[
    {"inputs": [{"internalType": "address", "name": "tokenA", "type": "address"}, {"internalType": "address", "name": "tokenB", "type": "address"}, {"internalType": "uint24", "name": "fee", "type": "uint24"}], "name": "getPool", "outputs": [{"internalType": "address", "name": "pool", "type": "address"}], "stateMutability": "view", "type": "function"}
]
''')

SWAP_ROUTER_ABI = json.loads('''
[
    {"inputs": [{"components": [{"internalType": "address", "name": "tokenIn", "type": "address"}, {"internalType": "address", "name": "tokenOut", "type": "address"}, {"internalType": "uint24", "name": "fee", "type": "uint24"}, {"internalType": "address", "name": "recipient", "type": "address"}, {"internalType": "uint256", "name": "deadline", "type": "uint256"}, {"internalType": "uint256", "name": "amountIn", "type": "uint256"}, {"internalType": "uint256", "name": "amountOutMinimum", "type": "uint256"}, {"internalType": "uint160", "name": "sqrtPriceLimitX96", "type": "uint160"}], "internalType": "struct ISwapRouter.ExactInputSingleParams", "name": "params", "type": "tuple"}], "name": "exactInputSingle", "outputs": [{"internalType": "uint256", "name": "amountOut", "type": "uint256"}], "stateMutability": "payable", "type": "function"}
]
''')

WETH9_ABI = json.loads('''
[
    {"constant": false, "inputs": [], "name": "deposit", "outputs": [], "payable": true, "stateMutability": "payable", "type": "function"},
    {"constant": false, "inputs": [{"name": "wad", "type": "uint256"}], "name": "withdraw", "outputs": [], "payable": false, "stateMutability": "nonpayable", "type": "function"}
]
''')

NONFUNGIBLE_POSITION_MANAGER_ADDRESS = bytes.fromhex("C36442b4" + "a4522E87" + "1399CD71" + "7aBDD847" + "Ab11FE88")
UNISWAP_V3_SWAP_ROUTER_ADDRESS = bytes.fromhex("E592427A0AEce92De3Edee1F18E0157C05861564")
WETH_ADDRESS = "0x82aF49447D8a07e3bd95BD0d56f35241523fBab1" # Arbitrum WETH

# --- Core Logic Functions ---
def get_position_details(w3_instance, npm_c, factory_c, token_id):
    try:
        position_data = npm_c.functions.positions(token_id).call()
        (nonce, operator, token0_address, token1_address, fee, tickLower, tickUpper, liquidity, 
         feeGrowthInside0, feeGrowthInside1, tokensOwed0, tokensOwed1) = position_data

        token0_contract = w3_instance.eth.contract(address=token0_address, abi=ERC20_ABI)
        token1_contract = w3_instance.eth.contract(address=token1_address, abi=ERC20_ABI)
        token0_symbol = token0_contract.functions.symbol().call()
        token1_symbol = token1_contract.functions.symbol().call()
        token0_decimals = token0_contract.functions.decimals().call()
        token1_decimals = token1_contract.functions.decimals().call()

        pool_address = factory_c.functions.getPool(token0_address, token1_address, fee).call()
        if pool_address == '0x0000000000000000000000000000000000000000':
            return None, None
        
        pool_contract = w3_instance.eth.contract(address=pool_address, abi=UNISWAP_V3_POOL_ABI)

        return {
            "token0_address": token0_address, "token1_address": token1_address,
            "token0_symbol": token0_symbol, "token1_symbol": token1_symbol,
            "token0_decimals": token0_decimals, "token1_decimals": token1_decimals,
            "fee": fee, "tickLower": tickLower, "tickUpper": tickUpper, "liquidity": liquidity,
            "pool_address": pool_address
        }, pool_contract
    except Exception as e:
        print(f"ERROR fetching position details: {e}")
        return None, None

def get_pool_dynamic_data(pool_c):
    try:
        slot0_data = pool_c.functions.slot0().call()
        return {"sqrtPriceX96": slot0_data[0], "tick": slot0_data[1]}
    except Exception as e:
        print(f"ERROR fetching pool dynamic data: {e}")
        return None

def calculate_mint_amounts(current_tick, tick_lower, tick_upper, investment_value_token1, decimals0, decimals1, sqrt_price_current_x96):
    sqrt_price_current = get_sqrt_ratio_at_tick(current_tick)
    sqrt_price_lower = get_sqrt_ratio_at_tick(tick_lower)
    sqrt_price_upper = get_sqrt_ratio_at_tick(tick_upper)
    
    # 1. Get Price of Token0 in terms of Token1
    price_of_token0_in_token1_units = price_from_sqrt_price_x96(sqrt_price_current_x96, decimals0, decimals1)
    
    # 2. Estimate Amounts
    L_test = 1 << 128
    amt0_test, amt1_test = get_amounts_for_liquidity(sqrt_price_current, sqrt_price_lower, sqrt_price_upper, L_test)
    
    # 3. Adjust for decimals
    real_amt0_test = amt0_test / (10**decimals0)
    real_amt1_test = amt1_test / (10**decimals1)
    
    # 4. Calculate Total Value of Test Position in Token1 terms
    value_test = (real_amt0_test * price_of_token0_in_token1_units) + real_amt1_test
    
    if value_test == 0:
        return 0, 0
        
    # 5. Scale
    scale = investment_value_token1 / value_test
    
    # 6. Final Amounts
    final_amt0 = int(amt0_test * scale)
    final_amt1 = int(amt1_test * scale)
    
    return final_amt0, final_amt1

def check_and_swap(w3_instance, router_contract, account, token0, token1, amount0_needed, amount1_needed):
    token0_contract = w3_instance.eth.contract(address=token0, abi=ERC20_ABI)
    token1_contract = w3_instance.eth.contract(address=token1, abi=ERC20_ABI)
    bal0 = token0_contract.functions.balanceOf(account.address).call()
    bal1 = token1_contract.functions.balanceOf(account.address).call()
    
    # Debug Balances
    s0 = token0_contract.functions.symbol().call()
    s1 = token1_contract.functions.symbol().call()
    d0 = token0_contract.functions.decimals().call()
    d1 = token1_contract.functions.decimals().call()
    
    print(f"\n--- WALLET CHECK ---")
    print(f"Required: {from_wei(amount0_needed, d0):.6f} {s0} | {from_wei(amount1_needed, d1):.2f} {s1}")
    print(f"Balance : {from_wei(bal0, d0):.6f} {s0} | {from_wei(bal1, d1):.2f} {s1}")
    
    deficit0 = max(0, amount0_needed - bal0)
    deficit1 = max(0, amount1_needed - bal1)
    
    if deficit0 > 0: print(f"Deficit {s0}: {from_wei(deficit0, d0):.6f}")
    if deficit1 > 0: print(f"Deficit {s1}: {from_wei(deficit1, d1):.2f}")
    
    # --- AUTO-WRAP ETH LOGIC ---
    weth_addr_lower = WETH_ADDRESS.lower()
    
    # Wrap for Token0 Deficit
    if (deficit0 > 0 or deficit1 > 0) and token0.lower() == weth_addr_lower:
        native_bal = w3_instance.eth.get_balance(account.address)
        gas_reserve = 5 * 10**15 # 0.005 ETH (Reduced for L2)
        available_native = max(0, native_bal - gas_reserve)
        
        amount_to_wrap = 0
        if deficit0 > 0:
            amount_to_wrap = deficit0
        
        if deficit1 > 0:
            amount_to_wrap = available_native
            
        amount_to_wrap = min(amount_to_wrap, available_native)
        
        if amount_to_wrap > 0:
            print(f"Auto-Wrapping {from_wei(amount_to_wrap, 18)} ETH to WETH...")
            weth_contract = w3_instance.eth.contract(address=token0, abi=WETH9_ABI)
            wrap_txn = weth_contract.functions.deposit().build_transaction({
                'from': account.address, 'value': amount_to_wrap, 'nonce': w3_instance.eth.get_transaction_count(account.address), 'gas': 100000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee, 'chainId': w3_instance.eth.chain_id
            })
            signed_wrap = w3_instance.eth.account.sign_transaction(wrap_txn, private_key=account.key)
            raw_wrap = signed_wrap.rawTransaction if hasattr(signed_wrap, 'rawTransaction') else signed_wrap.raw_transaction
            tx_hash = w3_instance.eth.send_raw_transaction(raw_wrap)
            print(f"Wrap Sent: {tx_hash.hex()}")
            w3_instance.eth.wait_for_transaction_receipt(tx_hash)
            bal0 = token0_contract.functions.balanceOf(account.address).call()
            deficit0 = max(0, amount0_needed - bal0) 
        else:
            if deficit0 > 0:
                 print(f"Insufficient Native ETH to wrap. Need: {from_wei(deficit0, 18)}, Available: {from_wei(available_native, 18)}")

    # Wrap for Token1 Deficit (if Token1 is WETH)
    if deficit1 > 0 and token1.lower() == weth_addr_lower:
        native_bal = w3_instance.eth.get_balance(account.address)
        gas_reserve = 5 * 10**15 # 0.005 ETH
        available_native = max(0, native_bal - gas_reserve)
        if available_native >= deficit1:
            print(f"Auto-Wrapping {from_wei(deficit1, 18)} ETH to WETH...")
            weth_contract = w3_instance.eth.contract(address=token1, abi=WETH9_ABI)
            wrap_txn = weth_contract.functions.deposit().build_transaction({
                'from': account.address, 'value': deficit1, 'nonce': w3_instance.eth.get_transaction_count(account.address), 'gas': 100000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee, 'chainId': w3_instance.eth.chain_id
            })
            signed_wrap = w3_instance.eth.account.sign_transaction(wrap_txn, private_key=account.key)
            raw_wrap = signed_wrap.rawTransaction if hasattr(signed_wrap, 'rawTransaction') else signed_wrap.raw_transaction
            tx_hash = w3_instance.eth.send_raw_transaction(raw_wrap)
            print(f"Wrap Sent: {tx_hash.hex()}")
            w3_instance.eth.wait_for_transaction_receipt(tx_hash)
            bal1 = token1_contract.functions.balanceOf(account.address).call()
            deficit1 = max(0, amount1_needed - bal1)

    if deficit0 == 0 and deficit1 == 0:
        return True

    if deficit0 > 0 and bal1 > amount1_needed:
        surplus1 = bal1 - amount1_needed
        print(f"Swapping surplus Token1 ({surplus1}) for Token0...")
        
        approve_txn = token1_contract.functions.approve(router_contract.address, surplus1).build_transaction({
            'from': account.address, 'nonce': w3_instance.eth.get_transaction_count(account.address),
            'gas': 100000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee,
            'chainId': w3_instance.eth.chain_id
        })
        signed = w3_instance.eth.account.sign_transaction(approve_txn, private_key=account.key)
        raw = signed.rawTransaction if hasattr(signed, 'rawTransaction') else signed.raw_transaction
        w3_instance.eth.send_raw_transaction(raw)
        time.sleep(2)
        
        params = (token1, token0, 500, account.address, int(time.time()) + 120, surplus1, 0, 0)
        swap_txn = router_contract.functions.exactInputSingle(params).build_transaction({
            'from': account.address, 'nonce': w3_instance.eth.get_transaction_count(account.address),
            'gas': 300000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee,
            'chainId': w3_instance.eth.chain_id
        })
        signed_swap = w3_instance.eth.account.sign_transaction(swap_txn, private_key=account.key)
        raw_swap = signed_swap.rawTransaction if hasattr(signed_swap, 'rawTransaction') else signed_swap.raw_transaction
        tx_hash = w3_instance.eth.send_raw_transaction(raw_swap)
        print(f"Swap Sent: {tx_hash.hex()}")
        w3_instance.eth.wait_for_transaction_receipt(tx_hash)
        
        # Verify Balance After Swap
        bal0 = token0_contract.functions.balanceOf(account.address).call()
        if bal0 < amount0_needed:
            print(f"❌ Swap insufficient. Have {bal0}, Need {amount0_needed}")
            return False
        return True

    elif deficit1 > 0 and bal0 > amount0_needed:
        surplus0 = bal0 - amount0_needed
        print(f"Swapping surplus Token0 ({surplus0}) for Token1...")
        
        approve_txn = token0_contract.functions.approve(router_contract.address, surplus0).build_transaction({
            'from': account.address, 'nonce': w3_instance.eth.get_transaction_count(account.address),
            'gas': 100000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee,
            'chainId': w3_instance.eth.chain_id
        })
        signed = w3_instance.eth.account.sign_transaction(approve_txn, private_key=account.key)
        raw = signed.rawTransaction if hasattr(signed, 'rawTransaction') else signed.raw_transaction
        w3_instance.eth.send_raw_transaction(raw)
        time.sleep(2)
        
        params = (token0, token1, 500, account.address, int(time.time()) + 120, surplus0, 0, 0)
        swap_txn = router_contract.functions.exactInputSingle(params).build_transaction({
            'from': account.address, 'nonce': w3_instance.eth.get_transaction_count(account.address),
            'gas': 300000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee,
            'chainId': w3_instance.eth.chain_id
        })
        signed_swap = w3_instance.eth.account.sign_transaction(swap_txn, private_key=account.key)
        raw_swap = signed_swap.rawTransaction if hasattr(signed_swap, 'rawTransaction') else signed_swap.raw_transaction
        tx_hash = w3_instance.eth.send_raw_transaction(raw_swap)
        print(f"Swap Sent: {tx_hash.hex()}")
        w3_instance.eth.wait_for_transaction_receipt(tx_hash)
        
        # Verify Balance After Swap
        bal1 = token1_contract.functions.balanceOf(account.address).call()
        if bal1 < amount1_needed:
            print(f"❌ Swap insufficient. Have {bal1}, Need {amount1_needed}")
            return False
        return True
    
    print("❌ Insufficient funds for required amounts.")
    return False

def get_token_balances(w3_instance, account_address, token0_address, token1_address):
    try:
        token0_contract = w3_instance.eth.contract(address=token0, abi=ERC20_ABI)
        token1_contract = w3_instance.eth.contract(address=token1, abi=ERC20_ABI)
        b0 = token0_contract.functions.balanceOf(account_address).call()
        b1 = token1_contract.functions.balanceOf(account_address).call()
        return b0, b1
    except: return 0, 0

def decrease_liquidity(w3_instance, npm_contract, account, position_id, liquidity_amount):
    try:
        txn = npm_contract.functions.decreaseLiquidity((position_id, liquidity_amount, 0, 0, int(time.time()) + 180)).build_transaction({
            'from': account.address, 'gas': 1000000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee, 'nonce': w3_instance.eth.get_transaction_count(account.address), 'chainId': w3_instance.eth.chain_id
        })
        signed = w3_instance.eth.account.sign_transaction(txn, private_key=account.key)
        raw = signed.rawTransaction if hasattr(signed, 'rawTransaction') else signed.raw_transaction
        tx_hash = w3_instance.eth.send_raw_transaction(raw)
        print(f"Decrease Sent: {tx_hash.hex()}")
        w3_instance.eth.wait_for_transaction_receipt(tx_hash)
        return True
    except Exception as e:
        print(f"Error decreasing: {e}")
        return False

def mint_new_position(w3_instance, npm_contract, account, token0, token1, amount0, amount1, tick_lower, tick_upper):
    print(f"\n--- Attempting to Mint ---")
    try:
        token0_c = w3_instance.eth.contract(address=token0, abi=ERC20_ABI)
        token1_c = w3_instance.eth.contract(address=token1, abi=ERC20_ABI)
        
        # Approve 0
        txn0 = token0_c.functions.approve(npm_contract.address, amount0).build_transaction({
            'from': account.address, 'nonce': w3_instance.eth.get_transaction_count(account.address),
            'gas': 100000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee, 'chainId': w3_instance.eth.chain_id
        })
        signed0 = w3_instance.eth.account.sign_transaction(txn0, private_key=account.key)
        raw0 = signed0.rawTransaction if hasattr(signed0, 'rawTransaction') else signed0.raw_transaction
        w3_instance.eth.send_raw_transaction(raw0)
        time.sleep(2)
        
        # Approve 1
        txn1 = token1_c.functions.approve(npm_contract.address, amount1).build_transaction({
            'from': account.address, 'nonce': w3_instance.eth.get_transaction_count(account.address),
            'gas': 100000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee, 'chainId': w3_instance.eth.chain_id
        })
        signed1 = w3_instance.eth.account.sign_transaction(txn1, private_key=account.key)
        raw1 = signed1.rawTransaction if hasattr(signed1, 'rawTransaction') else signed1.raw_transaction
        w3_instance.eth.send_raw_transaction(raw1)
        time.sleep(2)
        
        # Mint
        params = (token0, token1, 500, tick_lower, tick_upper, amount0, amount1, 0, 0, account.address, int(time.time()) + 180)
        mint_txn = npm_contract.functions.mint(params).build_transaction({
            'from': account.address, 'nonce': w3_instance.eth.get_transaction_count(account.address),
            'gas': 800000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee, 'chainId': w3_instance.eth.chain_id
        })
        signed_mint = w3_instance.eth.account.sign_transaction(mint_txn, private_key=account.key)
        raw_mint = signed_mint.rawTransaction if hasattr(signed_mint, 'rawTransaction') else signed_mint.raw_transaction
        tx_hash = w3_instance.eth.send_raw_transaction(raw_mint)
        print(f"Mint Sent: {tx_hash.hex()}")
        
        receipt = w3_instance.eth.wait_for_transaction_receipt(tx_hash)
        if receipt.status == 1:
            print("✅ Mint Successful!")
            
            result_data = {'token_id': None, 'liquidity': 0, 'amount0': 0, 'amount1': 0}
            
            # Web3.py Event Processing to capture ID and Amounts
            try:
                # 1. Capture Token ID from Transfer event
                transfer_events = npm_contract.events.Transfer().process_receipt(receipt)
                for event in transfer_events:
                    if event['args']['from'] == "0x0000000000000000000000000000000000000000":
                        result_data['token_id'] = event['args']['tokenId']
                        break
                
                # 2. Capture Amounts from IncreaseLiquidity event
                inc_liq_events = npm_contract.events.IncreaseLiquidity().process_receipt(receipt)
                for event in inc_liq_events:
                    if result_data['token_id'] and event['args']['tokenId'] == result_data['token_id']:
                        result_data['amount0'] = event['args']['amount0']
                        result_data['amount1'] = event['args']['amount1']
                        result_data['liquidity'] = event['args']['liquidity']
                        break
                        
            except Exception as e:
                print(f"Event Processing Warning: {e}")

            if result_data['token_id']:
                print(f"Captured: ID {result_data['token_id']}, Amt0 {result_data['amount0']}, Amt1 {result_data['amount1']}")
                return result_data
            
            return None
        else:
            print("❌ Mint Failed!")
            return None
    except Exception as e:
        print(f"Mint Error: {e}")
        return None

def collect_fees(w3_instance, npm_contract, account, position_id):
    try:
        txn = npm_contract.functions.collect((position_id, account.address, 2**128-1, 2**128-1)).build_transaction({
            'from': account.address, 'gas': 1000000, 'maxFeePerGas': w3_instance.eth.gas_price * 2, 'maxPriorityFeePerGas': w3_instance.eth.max_priority_fee, 'nonce': w3_instance.eth.get_transaction_count(account.address), 'chainId': w3_instance.eth.chain_id
        })
        signed = w3_instance.eth.account.sign_transaction(txn, private_key=account.key)
        raw = signed.rawTransaction if hasattr(signed, 'rawTransaction') else signed.raw_transaction
        tx_hash = w3_instance.eth.send_raw_transaction(raw)
        print(f"Collect Sent: {tx_hash.hex()}")
        w3_instance.eth.wait_for_transaction_receipt(tx_hash)
        return True
    except: return False

def main():
    print(f"CWD: {os.getcwd()}")
    # Load .env from current directory
    load_dotenv(override=True)
    
    rpc_url = os.environ.get("MAINNET_RPC_URL")
    private_key = os.environ.get("MAIN_WALLET_PRIVATE_KEY") or os.environ.get("PRIVATE_KEY")
    
    if not rpc_url or not private_key:
        print("Missing RPC or Private Key.")
        return

    w3 = Web3(Web3.HTTPProvider(rpc_url))
    if not w3.is_connected():
        print("RPC Connection Failed")
        return
    print(f"Connected to Chain ID: {w3.eth.chain_id}")
    
    account = Account.from_key(private_key)
    w3.eth.default_account = account.address
    print(f"Wallet: {account.address}")

    npm_contract = w3.eth.contract(address=NONFUNGIBLE_POSITION_MANAGER_ADDRESS, abi=NONFUNGIBLE_POSITION_MANAGER_ABI)
    factory_addr = npm_contract.functions.factory().call()
    factory_contract = w3.eth.contract(address=factory_addr, abi=UNISWAP_V3_FACTORY_ABI)
    router_contract = w3.eth.contract(address=UNISWAP_V3_SWAP_ROUTER_ADDRESS, abi=SWAP_ROUTER_ABI)

    print("\n--- STARTING LIFECYCLE MANAGER ---")
    while True:
        try:
            # 1. Get All Open Positions
            all_positions = get_all_open_positions()
            
            # Check if we have an active AUTOMATIC position
            active_automatic_position = next((p for p in all_positions if p['type'] == 'AUTOMATIC' and p['status'] == 'OPEN'), None)
            
            if all_positions:
                print("\n" + "="*60)
                print(f"Monitoring at: {time.strftime('%Y-%m-%d %H:%M:%S', time.localtime())}")
                
                for position in all_positions:
                    token_id = position['token_id']
                    pos_type = position['type']
                    
                    # Fetch Details
                    pos_details, pool_c = get_position_details(w3, npm_contract, factory_contract, token_id)
                    if not pos_details:
                        print(f"ERROR: Could not get details for Position {token_id}. Skipping.")
                        continue
                    
                    pool_data = get_pool_dynamic_data(pool_c)
                    current_tick = pool_data['tick']
                    
                    # Calculate Fees (Simulation)
                    unclaimed0 = 0
                    unclaimed1 = 0
                    try:
                        fees_sim = npm_contract.functions.collect((token_id, "0x0000000000000000000000000000000000000000", 2**128-1, 2**128-1)).call()
                        unclaimed0 = from_wei(fees_sim[0], pos_details['token0_decimals'])
                        unclaimed1 = from_wei(fees_sim[1], pos_details['token1_decimals'])
                    except: pass

                    # Check Range
                    is_out_of_range = False
                    status_str = "IN RANGE"
                    if current_tick < pos_details['tickLower']:
                        is_out_of_range = True
                        status_str = "OUT OF RANGE (BELOW)"
                    elif current_tick >= pos_details['tickUpper']:
                        is_out_of_range = True
                        status_str = "OUT OF RANGE (ABOVE)"
                        
                    print(f"\nID: {token_id} | Type: {pos_type} | Status: {status_str}")
                    print(f"  Range: {position['range_lower']:.2f} - {position['range_upper']:.2f}")
                    print(f"  Fees: {unclaimed0:.4f} {pos_details['token0_symbol']} / {unclaimed1:.4f} {pos_details['token1_symbol']}")

                    # --- AUTO CLOSE LOGIC (AUTOMATIC ONLY) ---
                    if pos_type == 'AUTOMATIC' and CLOSE_POSITION_ENABLED and is_out_of_range:
                        print(f"⚠️ Automatic Position {token_id} is OUT OF RANGE! Initiating Close...")
                        liq = pos_details['liquidity']
                        if liq > 0:
                            if decrease_liquidity(w3, npm_contract, account, token_id, liq):
                                time.sleep(5)
                                collect_fees(w3, npm_contract, account, token_id)
                                update_hedge_status_file("CLOSE", {'token_id': token_id})
                                print("Position Closed & Status Updated.")
                                
                                # --- REBALANCE ON CLOSE (If Price Dropped) ---
                                if REBALANCE_ON_CLOSE_BELOW_RANGE and status_str == "OUT OF RANGE (BELOW)":
                                    print("📉 Position closed BELOW range (100% ETH). Selling 50% of WETH inventory to USDC...")
                                    try:
                                        # Get WETH Balance
                                        token0_c = w3.eth.contract(address=pos_details['token0_address'], abi=ERC20_ABI)
                                        weth_bal = token0_c.functions.balanceOf(account.address).call()
                                        
                                        amount_in = weth_bal // 2
                                        
                                        if amount_in > 0:
                                            # Approve Router
                                            approve_txn = token0_c.functions.approve(router_contract.address, amount_in).build_transaction({
                                                'from': account.address, 'nonce': w3.eth.get_transaction_count(account.address),
                                                'gas': 100000, 'maxFeePerGas': w3.eth.gas_price * 2, 'maxPriorityFeePerGas': w3.eth.max_priority_fee,
                                                'chainId': w3.eth.chain_id
                                            })
                                            signed = w3.eth.account.sign_transaction(approve_txn, private_key=account.key)
                                            raw = signed.rawTransaction if hasattr(signed, 'rawTransaction') else signed.raw_transaction
                                            w3.eth.send_raw_transaction(raw)
                                            time.sleep(2)
                                            
                                            # Swap WETH -> USDC
                                            params = (pos_details['token0_address'], pos_details['token1_address'], 500, account.address, int(time.time()) + 120, amount_in, 0, 0)
                                            swap_txn = router_contract.functions.exactInputSingle(params).build_transaction({
                                                'from': account.address, 'nonce': w3.eth.get_transaction_count(account.address),
                                                'gas': 300000, 'maxFeePerGas': w3.eth.gas_price * 2, 'maxPriorityFeePerGas': w3.eth.max_priority_fee,
                                                'chainId': w3.eth.chain_id
                                            })
                                            signed_swap = w3.eth.account.sign_transaction(swap_txn, private_key=account.key)
                                            raw_swap = signed_swap.rawTransaction if hasattr(signed_swap, 'rawTransaction') else signed_swap.raw_transaction
                                            tx_hash = w3.eth.send_raw_transaction(raw_swap)
                                            print(f"⚖️ Rebalance Swap Sent: {tx_hash.hex()}")
                                            w3.eth.wait_for_transaction_receipt(tx_hash)
                                            print("✅ Rebalance Complete.")
                                    except Exception as e:
                                        print(f"Error during rebalance swap: {e}")

                        else:
                            print("Liquidity 0. Marking closed.")
                            update_hedge_status_file("CLOSE", {'token_id': token_id})

            # 2. Opening Logic (If no active automatic position)
            if not active_automatic_position and OPEN_POSITION_ENABLED:
                print("\n[OPENING] No active automatic position. Starting Open Sequence...")
                # Get Pool (WETH/USDC)
                token0 = "0x82aF49447D8a07e3bd95BD0d56f35241523fBab1" # WETH
                token1 = "0xaf88d065e77c8cC2239327C5EDb3A432268e5831" # USDC
                pool_addr = factory_contract.functions.getPool(token0, token1, 500).call()
                pool_c = w3.eth.contract(address=pool_addr, abi=UNISWAP_V3_POOL_ABI)
                
                pool_data = get_pool_dynamic_data(pool_c)
                tick = pool_data['tick']
                
                # Range +/- 2%
                import math
                tick_delta = int(math.log(1 + RANGE_WIDTH_PCT) / math.log(1.0001))
                spacing = 10
                lower = (tick - tick_delta) // spacing * spacing
                upper = (tick + tick_delta) // spacing * spacing
                
                # Amounts
                try:
                    token0_c = w3.eth.contract(address=token0, abi=ERC20_ABI)
                    token1_c = w3.eth.contract(address=token1, abi=ERC20_ABI)
                    d0 = token0_c.functions.decimals().call()
                    d1 = token1_c.functions.decimals().call()
                except Exception as e:
                    print(f"Error fetching decimals: {e}")
                    time.sleep(MONITOR_INTERVAL_SECONDS)
                    continue
                
                amt0, amt1 = calculate_mint_amounts(tick, lower, upper, TARGET_INVESTMENT_VALUE_TOKEN1, d0, d1, pool_data['sqrtPriceX96'])
                amt0_buf, amt1_buf = int(amt0 * 1.02), int(amt1 * 1.02)
                
                if check_and_swap(w3, router_contract, account, token0, token1, amt0_buf, amt1_buf):
                    mint_result = mint_new_position(w3, npm_contract, account, token0, token1, amt0, amt1, lower, upper)
                    
                    if mint_result: # Calculate Actual Value
                        try:
                            s0 = token0_c.functions.symbol().call()
                            s1 = token1_c.functions.symbol().call()
                        except:
                            s0, s1 = "T0", "T1"

                        real_amt0 = from_wei(mint_result['amount0'], d0)
                        real_amt1 = from_wei(mint_result['amount1'], d1)
                        entry_price = price_from_sqrt_price_x96(pool_data['sqrtPriceX96'], d0, d1)
                        actual_value = (real_amt0 * entry_price) + real_amt1
                        print(f"ACTUAL MINT VALUE: {actual_value:.2f} {s1}/{s0}")
                        
                        pos_data = {
                            'token_id': mint_result['token_id'],
                            'entry_price': entry_price,
                            'range_lower': price_from_tick(lower, d0, d1),
                            'range_upper': price_from_tick(upper, d0, d1),
                            'target_value': actual_value,
                            'amount0_initial': mint_result['amount0'],
                            'amount1_initial': mint_result['amount1']
                        }
                        update_hedge_status_file("OPEN", pos_data)
                        print("Cycle Complete. Monitoring.")
            
            elif not all_positions:
                 print("No open positions (Manual or Automatic). Waiting...")

            time.sleep(MONITOR_INTERVAL_SECONDS)
            
        except KeyboardInterrupt:
            print("\nManager stopped.")
            break
        except Exception as e:
            print(f"Error in Main Loop: {e}")
            time.sleep(MONITOR_INTERVAL_SECONDS)

if __name__ == "__main__":
    main()