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"""
Geo-Lab AI Engine: ์นจ์‹ ๋กœ์ง
Stream Power Law ๊ธฐ๋ฐ˜ ํ•˜๋ฐฉ/์ธก๋ฐฉ ์นจ์‹ ๊ตฌํ˜„
"""
import numpy as np
from typing import TYPE_CHECKING

if TYPE_CHECKING:
    from .base import Terrain, Water


def vertical_erosion(terrain: 'Terrain', water: 'Water', 
                     k_erosion: float = 0.0001,
                     m_exponent: float = 0.5,
                     n_exponent: float = 1.0,
                     dt: float = 1.0) -> np.ndarray:
    """
    ํ•˜๋ฐฉ ์นจ์‹ (Vertical/Downcutting Erosion)
    Stream Power Law: E = K * A^m * S^n
    
    Parameters:
    -----------
    terrain : Terrain
        ์ง€ํ˜• ๊ฐ์ฒด
    water : Water
        ์ˆ˜๋ฌธ ๊ฐ์ฒด
    k_erosion : float
        ์นจ์‹ ๊ณ„์ˆ˜ (์•”์„ ๊ฒฝ๋„์˜ ์—ญ์ˆ˜)
    m_exponent : float
        ์œ ๋Ÿ‰ ์ง€์ˆ˜ (๋ณดํ†ต 0.4-0.6)
    n_exponent : float
        ๊ฒฝ์‚ฌ ์ง€์ˆ˜ (๋ณดํ†ต 1.0)
    dt : float
        ์‹œ๊ฐ„ ๋‹จ์œ„ (๋…„)
    
    Returns:
    --------
    erosion_amount : np.ndarray
        ๊ฐ ์…€์˜ ์นจ์‹๋Ÿ‰ (m)
    """
    # ๊ฒฝ์‚ฌ ๊ณ„์‚ฐ
    slope = terrain.get_slope()
    
    # Stream Power Law
    # E = K * Q^m * S^n
    # ์•”์„ ๊ฒฝ๋„๋กœ K ์กฐ์ ˆ (๊ฒฝ๋„๊ฐ€ ๋†’์œผ๋ฉด ์นจ์‹์ด ์ ์Œ)
    effective_k = k_erosion * (1 - terrain.rock_hardness * 0.9)
    
    erosion_rate = effective_k * np.power(water.discharge + 0.1, m_exponent) * np.power(slope + 0.001, n_exponent)
    
    erosion_amount = erosion_rate * dt
    
    # ์นจ์‹๋Ÿ‰ ์ œํ•œ (๋„ˆ๋ฌด ๊ธ‰๊ฒฉํ•œ ๋ณ€ํ™” ๋ฐฉ์ง€)
    max_erosion = 10.0  # ์ตœ๋Œ€ 10m/yr
    erosion_amount = np.clip(erosion_amount, 0, max_erosion)
    
    return erosion_amount


def lateral_erosion(terrain: 'Terrain', water: 'Water',
                    k_lateral: float = 0.00005,
                    curvature_factor: float = 1.0,
                    dt: float = 1.0) -> np.ndarray:
    """
    ์ธก๋ฐฉ ์นจ์‹ (Lateral Erosion)
    ๊ณก๋ฅ˜ ํ•˜์ฒœ์—์„œ ๋ฐ”๊นฅ์ชฝ(๊ณต๊ฒฉ์‚ฌ๋ฉด)์„ ๊นŽ์Œ
    
    Parameters:
    -----------
    terrain : Terrain
        ์ง€ํ˜• ๊ฐ์ฒด
    water : Water
        ์ˆ˜๋ฌธ ๊ฐ์ฒด
    k_lateral : float
        ์ธก๋ฐฉ ์นจ์‹ ๊ณ„์ˆ˜
    curvature_factor : float
        ๊ณก๋ฅ  ๊ฐ•์กฐ ๊ณ„์ˆ˜
    dt : float
        ์‹œ๊ฐ„ ๋‹จ์œ„ (๋…„)
    
    Returns:
    --------
    erosion_amount : np.ndarray
        ๊ฐ ์…€์˜ ์นจ์‹๋Ÿ‰ (m)
    """
    h, w = terrain.height, terrain.width
    erosion = np.zeros((h, w))
    
    # ์œ ๋กœ ๊ณก๋ฅ  ๊ณ„์‚ฐ (ํ๋ฆ„ ๋ฐฉํ–ฅ์˜ 2์ฐจ ๋ฏธ๋ถ„)
    flow_x, flow_y = water.flow_x, water.flow_y
    
    # ๊ณก๋ฅ  ๊ทผ์‚ฌ: ํ๋ฆ„ ๋ฐฉํ–ฅ์˜ ๋ณ€ํ™”์œจ
    curvature_x = np.gradient(flow_x, axis=1)
    curvature_y = np.gradient(flow_y, axis=0)
    curvature = np.sqrt(curvature_x**2 + curvature_y**2)
    
    # ์ธก๋ฐฉ ์นจ์‹ = ์œ ๋Ÿ‰ * ์œ ์† * ๊ณก๋ฅ 
    # ๊ณก๋ฅ ์ด ํฐ ๊ณณ(๊ธ‰์ปค๋ธŒ) = ๋ฐ”๊นฅ์ชฝ ์นจ์‹ ๊ฐ•ํ•จ
    erosion = k_lateral * water.discharge * water.velocity * curvature * curvature_factor * dt
    
    # ํ•˜์ฒœ์ด ์žˆ๋Š” ๊ณณ์—์„œ๋งŒ ์นจ์‹ (์œ ๋Ÿ‰ ์ž„๊ณ„๊ฐ’)
    channel_mask = water.discharge > 0.1
    erosion = erosion * channel_mask
    
    return np.clip(erosion, 0, 5.0)


def headward_erosion(terrain: 'Terrain', water: 'Water',
                     k_headward: float = 0.0002,
                     dt: float = 1.0) -> np.ndarray:
    """
    ๋‘๋ถ€ ์นจ์‹ (Headward Erosion)
    ํ•˜์ฒœ์˜ ์ƒ๋ฅ˜ ๋์ด ์ ์  ๋’ค๋กœ ๋ฌผ๋Ÿฌ๋‚จ
    ํญํฌ, ํ˜‘๊ณก ํ˜•์„ฑ์˜ ํ•ต์‹ฌ ๋ฉ”์ปค๋‹ˆ์ฆ˜
    
    Returns:
    --------
    erosion_amount : np.ndarray
        ๊ฐ ์…€์˜ ์นจ์‹๋Ÿ‰ (m)
    """
    h, w = terrain.height, terrain.width
    erosion = np.zeros((h, w))
    
    # ๊ธ‰๊ฒฝ์‚ฌ ์ง€์ (Knickpoint) ์ฐพ๊ธฐ
    slope = terrain.get_slope()
    steep_mask = slope > np.percentile(slope[slope > 0], 90)  # ์ƒ์œ„ 10% ๊ธ‰๊ฒฝ์‚ฌ
    
    # ๊ธ‰๊ฒฝ์‚ฌ + ์œ ๋Ÿ‰์ด ์žˆ๋Š” ๊ณณ์—์„œ ๋‘๋ถ€ ์นจ์‹ ๋ฐœ์ƒ
    channel_mask = water.discharge > 0.5
    knickpoint_mask = steep_mask & channel_mask
    
    # ์ƒ๋ฅ˜ ๋ฐฉํ–ฅ์œผ๋กœ ์นจ์‹ ํ™•์žฅ
    erosion[knickpoint_mask] = k_headward * water.discharge[knickpoint_mask] * dt
    
    return np.clip(erosion, 0, 2.0)


def apply_erosion(terrain: 'Terrain', erosion_amount: np.ndarray,
                  min_elevation: float = 0.0):
    """
    ์ง€ํ˜•์— ์นจ์‹ ์ ์šฉ
    
    Parameters:
    -----------
    terrain : Terrain
        ์ˆ˜์ •ํ•  ์ง€ํ˜• ๊ฐ์ฒด
    erosion_amount : np.ndarray
        ์นจ์‹๋Ÿ‰ ๋ฐฐ์—ด
    min_elevation : float
        ์ตœ์†Œ ๊ณ ๋„ (ํ•ด์ˆ˜๋ฉด)
    """
    terrain.elevation -= erosion_amount
    terrain.elevation = np.maximum(terrain.elevation, min_elevation)


def mass_wasting(terrain: 'Terrain', 
                 critical_slope: float = 0.7,  # ~35๋„
                 transfer_rate: float = 0.3) -> np.ndarray:
    """
    ์‚ฌ๋ฉด ๋ถ•๊ดด (Mass Wasting)
    V์ž๊ณก ํ˜•์„ฑ ์‹œ ์–‘์˜† ์‚ฌ๋ฉด์ด ๋ฌด๋„ˆ์ง€๋Š” ๊ณผ์ •
    
    Returns:
    --------
    elevation_change : np.ndarray
        ๊ณ ๋„ ๋ณ€ํ™”๋Ÿ‰ (๋†’์€ ๊ณณ -, ๋‚ฎ์€ ๊ณณ +)
    """
    h, w = terrain.height, terrain.width
    change = np.zeros((h, w))
    
    slope = terrain.get_slope()
    
    # ์ž„๊ณ„ ๊ฒฝ์‚ฌ ์ดˆ๊ณผ ์ง€์ ์—์„œ ๋ฌผ์งˆ ์ด๋™
    unstable = slope > critical_slope
    
    for y in range(1, h-1):
        for x in range(1, w-1):
            if unstable[y, x]:
                # ์ฃผ๋ณ€์œผ๋กœ ๋ฌผ์งˆ ๋ถ„๋ฐฐ
                elev = terrain.elevation[y, x]
                neighbors = [
                    (y-1, x), (y+1, x), (y, x-1), (y, x+1)
                ]
                
                for ny, nx in neighbors:
                    if terrain.elevation[ny, nx] < elev:
                        transfer = (elev - terrain.elevation[ny, nx]) * transfer_rate * 0.25
                        change[y, x] -= transfer
                        change[ny, nx] += transfer
    
    return change