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from .grid import WorldGrid
try:
from numba import jit
HAS_NUMBA = True
except ImportError:
HAS_NUMBA = False
# Dummy decorator if numba is missing
def jit(*args, **kwargs):
def decorator(func):
return func
return decorator
@jit(nopython=True)
def _d8_flow_kernel(elev, discharge, flow_dir, underwater, h, w):
"""
Numba-optimized D8 Flow Routing
"""
# Flatten elevation to sort
flat_elev = elev.ravel()
# Sort indices descending (Source -> Sink)
# Note: argsort in numba supports 1D array
flat_indices = np.argsort(flat_elev)[::-1]
# 8-neighbor offsets
# Numba doesn't like list of tuples in loops sometimes, simple arrays are better
dr = np.array([-1, -1, -1, 0, 0, 1, 1, 1])
dc = np.array([-1, 0, 1, -1, 1, -1, 0, 1])
for i in range(len(flat_indices)):
idx = flat_indices[i]
r = idx // w
c = idx % w
# Check underwater
if underwater[r, c]:
continue
current_z = elev[r, c]
min_z = current_z
target_r = -1
target_c = -1
target_k = -1
# Find steepest descent
for k in range(8):
nr = r + dr[k]
nc = c + dc[k]
if 0 <= nr < h and 0 <= nc < w:
n_elev = elev[nr, nc]
if n_elev < min_z:
min_z = n_elev
target_r = nr
target_c = nc
target_k = k
# Pass flow to lowest neighbor
if target_r != -1:
discharge[target_r, target_c] += discharge[r, c]
flow_dir[r, c] = target_k # Store direction (0-7)
class HydroKernel:
"""
์๋ ฅํ ์ปค๋ (Hydro Kernel)
๋ฌผ์ ํ๋ฆ๊ณผ ๋ถํฌ๋ฅผ ์๋ฎฌ๋ ์ด์
ํฉ๋๋ค.
- D8 ์๊ณ ๋ฆฌ์ฆ: ํ์ฒ ๋คํธ์ํฌ ํ์ฑ (Numba ๊ฐ์ ์ ์ฉ)
- Shallow Water (๊ฐ์ํ): ํ์ ๋ฐ ํด์๋ฉด ์นจ์
"""
def __init__(self, grid: WorldGrid):
self.grid = grid
def route_flow_d8(self, precipitation: float = 0.001) -> np.ndarray:
"""
D8 ์๊ณ ๋ฆฌ์ฆ์ผ๋ก ์ ๋(Discharge) ๊ณ์ฐ (Numba ๊ฐ์)
"""
h, w = self.grid.height, self.grid.width
elev = self.grid.elevation
# 1. ์ด๊ธฐ ๊ฐ์ ๋ถํฌ
discharge = np.full((h, w), precipitation * (self.grid.cell_size ** 2), dtype=np.float64)
# 2. ํด์๋ฉด ๋ง์คํฌ
underwater = self.grid.is_underwater()
# 3. Numba Kernel ํธ์ถ
if HAS_NUMBA:
_d8_flow_kernel(elev, discharge, self.grid.flow_dir, underwater, h, w)
else:
# Fallback (Slow Python) if numba somehow fails to import
self._route_flow_d8_python(discharge, self.grid.flow_dir, elev, underwater, h, w)
return discharge
def route_flow_mfd(self, precipitation: float = 0.001, p: float = 1.1) -> np.ndarray:
"""
MFD (Multiple Flow Direction) ์ ๋ ๋ถ๋ฐฐ
D8๊ณผ ๋ฌ๋ฆฌ ๋ฎ์ ๋ชจ๋ ์ด์์๊ฒ ๊ฒฝ์ฌ ๋น๋ก๋ก ์ ๋ ๋ถ๋ฐฐ.
๋ง๋ฅ(Braided Stream) ๋ฐ ๋ถ๊ธฐ๋ฅ ํํ์ ์ ํฉ.
Args:
precipitation: ๊ฐ์๋
p: ๋ถ๋ฐฐ ์ง์ (1.0=์ ํ, >1.0=๊ฐํ๋ฅธ ๊ณณ์ ์ง์ค)
Returns:
discharge: ์ ๋ ๋ฐฐ์ด
"""
h, w = self.grid.height, self.grid.width
elev = self.grid.elevation
# ์ด๊ธฐ ๊ฐ์
discharge = np.full((h, w), precipitation * (self.grid.cell_size ** 2), dtype=np.float64)
# ํด์๋ฉด ๋ง์คํฌ
underwater = self.grid.is_underwater()
# D8 ๋ฐฉํฅ ๋ฒกํฐ
dr = np.array([-1, -1, -1, 0, 0, 1, 1, 1])
dc = np.array([-1, 0, 1, -1, 1, -1, 0, 1])
dist = np.array([1.414, 1.0, 1.414, 1.0, 1.0, 1.414, 1.0, 1.414]) # ๋๊ฐ ๊ฑฐ๋ฆฌ
# ์ ๋ ฌ (๋์ ๊ณณ -> ๋ฎ์ ๊ณณ)
flat_indices = np.argsort(elev.ravel())[::-1]
for idx in flat_indices:
r, c = idx // w, idx % w
if underwater[r, c]:
continue
current_z = elev[r, c]
current_q = discharge[r, c]
if current_q <= 0:
continue
# ๋ฎ์ ์ด์๋ค์ ๊ฒฝ์ฌ ๊ณ์ฐ
slopes = []
targets = []
for k in range(8):
nr, nc = r + dr[k], c + dc[k]
if 0 <= nr < h and 0 <= nc < w:
dz = current_z - elev[nr, nc]
if dz > 0: # ํ๊ฐํ๋ ๋ฐฉํฅ๋ง
slope = dz / (dist[k] * self.grid.cell_size)
slopes.append(slope ** p)
targets.append((nr, nc))
if not slopes:
continue
# ๊ฒฝ์ฌ ๋น๋ก ๋ถ๋ฐฐ
total_slope = sum(slopes)
for i, (nr, nc) in enumerate(targets):
fraction = slopes[i] / total_slope
discharge[nr, nc] += current_q * fraction
return discharge
def _route_flow_d8_python(self, discharge, flow_dir, elev, underwater, h, w):
"""Legacy Python implementation for fallback"""
flat_indices = np.argsort(elev.ravel())[::-1]
neighbors = [(-1,-1), (-1,0), (-1,1), (0,-1), (0,1), (1,-1), (1,0), (1,1)]
for idx in flat_indices:
r, c = idx // w, idx % w
if underwater[r, c]: continue
min_z = elev[r, c]
target = None
target_k = -1
for k, (dr, dc) in enumerate(neighbors):
nr, nc = r + dr, c + dc
if 0 <= nr < h and 0 <= nc < w:
if elev[nr, nc] < min_z:
min_z = elev[nr, nc]
target = (nr, nc)
target_k = k
if target:
tr, tc = target
discharge[tr, tc] += discharge[r, c]
flow_dir[r, c] = target_k
def calculate_water_depth(self, discharge: np.ndarray, manning_n: float = 0.03) -> np.ndarray:
"""
Manning ๊ณต์์ ์ด์ฉํ ํ์ฒ ์์ฌ ์ถ์ (์ ์ ๋ฑ๋ฅ ๊ฐ์ )
Depth = (Q * n / (Width * S^0.5))^(3/5)
* ๊ฒฝ์ฌ(S)๊ฐ 0์ธ ๊ฒฝ์ฐ ์ต์ ๊ฒฝ์ฌ ์ ์ฉ
* ํํญ(W)์ ์ ๋(Q)์ ํจ์๋ก ๊ฐ์ (W ~ Q^0.5)
"""
slope, _ = self.grid.get_gradient()
slope = np.maximum(slope, 0.001) # ์ต์ ๊ฒฝ์ฌ ์ค์
# ํํญ ์ถ์ : W = 5 * Q^0.5 (๊ฒฝํ์)
# Q๊ฐ ๋งค์ฐ ์์ผ๋ฉด W๋ ์์์ง
width = 5.0 * np.sqrt(discharge)
width = np.maximum(width, 1.0) # ์ต์ ํญ 1m
# ์์ฌ ๊ณ์ฐ
# Q = V * Area = (1/n * R^(2/3) * S^(1/2)) * (W * D)
# ์ง์ฌ๊ฐํ ๋จ๋ฉด ๊ฐ์ ์ R approx D (๋์ ํ์ฒ)
# Q = (1/n) * D^(5/3) * W * S^(1/2)
# D = (Q * n / (W * S^0.5)) ^ (3/5)
val = (discharge * manning_n) / (width * np.sqrt(slope))
depth = np.power(val, 0.6)
return depth
def simulate_inundation(self):
"""ํด์๋ฉด ์์น์ ๋ฐ๋ฅธ ์นจ์ ์๋ฎฌ๋ ์ด์
"""
# ํด์๋ฉด๋ณด๋ค ๋ฎ์ ๊ณณ์ ๋ฐ๋ค๋ก ๊ฐ์ฃผํ๊ณ ์์ฌ์ ์ฑ์
underwater = self.grid.is_underwater()
# ๋ฐ๋ค ์์ฌ = ํด์๋ฉด - ์งํ๋ฉด๊ณ ๋
sea_depth = np.maximum(0, self.grid.sea_level - self.grid.elevation)
# ๊ธฐ์กด ์์ฌ(ํ์ฒ)๊ณผ ๋ฐ๋ค ์์ฌ ์ค ํฐ ๊ฐ ์ ํ
# (ํ์ฒ์ด ๋ฐ๋ค๋ก ๋ค์ด๊ฐ๋ฉด ๋ฐ๋ค ์์ฌ์ ๋ฌปํ)
self.grid.water_depth = np.where(underwater, sea_depth, self.grid.water_depth)
def fill_sinks(self, max_iterations: int = 100, tolerance: float = 0.001):
"""
์ฑํฌ(์
๋ฉ์ด) ์ฑ์ฐ๊ธฐ - ํธ์ ํ์ฑ
๋ฌผ์ด ๊ฐํ๋ ๊ณณ์ ์ฐพ์ ์ฑ์์ ์๋ฅ(Overflow)๊ฐ ๊ฐ๋ฅํ๋๋ก ํจ.
๊ฐ๋จํ ๋ฐ๋ณต ์ค๋ฌด๋ฉ ๋ฐฉ์ (Priority-Flood ๊ทผ์ฌ)
Args:
max_iterations: ์ต๋ ๋ฐ๋ณต ํ์
tolerance: ์๋ ด ํ์ฉ ์ค์ฐจ
"""
h, w = self.grid.height, self.grid.width
elev = self.grid.elevation.copy()
# ๊ฒฝ๊ณ๋ ๊ณ ์ (๋ฌผ์ด ๋น ์ ธ๋๊ฐ)
# ๋ด๋ถ ์ฑํฌ๋ง ์ฑ์
dr = [-1, -1, -1, 0, 0, 1, 1, 1]
dc = [-1, 0, 1, -1, 1, -1, 0, 1]
for iteration in range(max_iterations):
changed = False
new_elev = elev.copy()
for r in range(1, h - 1):
for c in range(1, w - 1):
current = elev[r, c]
# ์ด์ ์ค ์ต์๊ฐ ์ฐพ๊ธฐ
min_neighbor = current
for k in range(8):
nr, nc = r + dr[k], c + dc[k]
if 0 <= nr < h and 0 <= nc < w:
min_neighbor = min(min_neighbor, elev[nr, nc])
# ๋ชจ๋ ์ด์๋ณด๋ค ๋ฎ์ผ๋ฉด (์ฑํฌ) โ ์ต์ ์ด์ ๋์ด๋ก ๋ง์ถค
if current < min_neighbor:
# ์ด์ง ๋์ฌ์ ํ๋ฆ ์ ๋
new_elev[r, c] = min_neighbor + tolerance
changed = True
elev = new_elev
if not changed:
break
# ์ฑ์์ง ์ = ์ ๊ณ ๋ - ๊ธฐ์กด ๊ณ ๋
fill_amount = elev - self.grid.elevation
# ๋ฌผ๋ก ์ฑ์์ง ๊ฒ์ผ๋ก ์ฒ๋ฆฌ (water_depth ์ฆ๊ฐ)
self.grid.water_depth += np.maximum(fill_amount, 0)
# bedrock์ ๊ทธ๋๋ก, sediment๋ ๊ทธ๋๋ก (๋ฌผ๋ง ์ฑ์)
# ๋๋ sediment๋ก ์ฑ์ธ ์๋ ์์ (ํธ์ ํด์ )
return fill_amount
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