mosse correlation
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7ebd03ec98
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14 changed files with 476 additions and 173 deletions
1
.gitignore
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**/*.egg-info
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**/*.egg-info
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/dist
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/dist
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**/__pycache__/
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134
demo/mosse_viz.py
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134
demo/mosse_viz.py
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import numpy as np
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import scipy.signal as signal
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from scipy.fftpack import fft, fftshift, ifft
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import matplotlib.pyplot as plt
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from matplotlib.widgets import Slider
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N = 256
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def gaussian_filter1d(size,sigma):
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filter_range = np.linspace(-int(size/2),int(size/2),size)
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gaussian_filter = [1 / (sigma * np.sqrt(2*np.pi)) * np.exp(-x**2/(2*sigma**2)) for x in filter_range]
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return gaussian_filter
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def generate_signal(N:int) -> np.ndarray:
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x = np.arange(1, N)
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y = np.zeros((N))
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for i in range(len(x)):
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y[i] = np.random.normal(scale=1) + (y[i-1] if i > 1 else 0)
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return np.convolve(y,gaussian_filter1d(N,1),'same')
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if __name__ == '__main__':
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np.random.seed(42)
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f_full = generate_signal(2048)
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x = np.arange(-180,180,360/N)
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f = f_full[1024:1024+N]
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h = f_full[1024:1024+N]
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g = signal.gaussian(N, std=10,sym=True)
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F = fft(f)
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F_ = np.conjugate(F)
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G = fft(g)
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K_ = (G*F_)/(F*F_)
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H = fft(h)
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r = ifft(H*K_)
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# ==========================================
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fig, (ax1, ax2, ax3, ax4, ax5, ax6, ax7) = plt.subplots(7, 1, gridspec_kw={'height_ratios':[4,4,4,1,1,1,1]})
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ax1.set_title('Terrain')
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plt_f, = ax1.plot(x,f)
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plt_h, = ax1.plot(x,h)
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ax2.set_title('MOSSE response signal')
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ax2.set_ylim([0, 1.2])
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line_r = ax2.axvline(x=-N//2+np.argmax(abs(r)), color='r')
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plt_r, = ax2.plot(x,abs(r))
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plt_r2, = ax2.plot(x,abs(r))
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ax3.set_title('Gaussian')
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plt_g, = ax3.plot(x,g)
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ax1.set_xlim([-180,180])
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ax2.set_xlim([-180,180])
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ax3.set_xlim([-180,180])
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slider1 = Slider(ax4, 'sigma', 0.3, 10, valinit=0.1)
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slider2 = Slider(ax5, 'shift', -N//2 , N//2, valinit=0, valstep=1)
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slider3 = Slider(ax6, 'seed', 0 , 50, valinit=0, valstep=1)
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slider4 = Slider(ax7, 'N', 128 , 1024, valinit=256, valstep=8)
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sigma = 0.3
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shift = 0
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def update():
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# K_ = (G*F_)/(F*F_)
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window = np.ones((N)) #signal.windows.hamming(N)
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H = fft(h*window)
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F = fft(f*window)
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R = H*G/F
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r = ifft(R)
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s = np.argmax(abs(r))
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r2 = np.copy(r)
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r2[s-5:s+5] = 0
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plt_g.set_data(x,g)
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plt_r.set_data(x,abs(r))
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plt_r2.set_data(x,abs(r2))
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plt_h.set_data(x,h)
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plt_f.set_data(x,f)
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ax1.set_ylim([min(np.min(h),np.min(f))-1, max(np.max(h),np.max(f))+1])
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ax2.set_ylim([0, np.max(r)+0.2])
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line_r.set_xdata(round((np.argmax(abs(r))/N-0.5)*360))
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fig.canvas.draw_idle()
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def update_sigma(val):
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global g, G, sigma, N
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sigma = val
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g = signal.gaussian(N, std=sigma,sym=True)
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G = fft(g)
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update()
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def update_shift(val):
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global shift, H, h
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shift = -val
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h = f_full[1024+round(shift*(N/360)):1024+N+round(shift*(N/360))]
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noise = np.random.normal(0,0.5, N)
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h = h+noise
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update()
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def update_seed(val):
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global f_full, f, h, F, H, F_, shift
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np.random.seed(val)
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f_full = generate_signal(2048)
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f = f_full[1024:1024+N]
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h = f_full[1024+round(shift*(N/360)):1024+N+round(shift*(N/360))]
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noise = np.random.normal(0,0.5, N)
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h = h+noise
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update()
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def update_n(val):
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global g, G, N, f_full, f, h, F, H, F_, shift, x, sigma, slider2
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N = val
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x = np.arange(-180,180,360/N)
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g = signal.gaussian(N, std=sigma,sym=True)
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G = fft(g)
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f = f_full[1024:1024+N]
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h = f_full[1024+shift:1024+N+shift]
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noise = np.random.normal(0,0.5, N)
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h = h+noise
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update()
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slider1.on_changed(update_sigma)
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slider2.on_changed(update_shift)
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slider3.on_changed(update_seed)
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slider4.on_changed(update_n)
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plt.subplots_adjust(hspace=0.5)
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plt.show()
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54
demo/test_terrain.py
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demo/test_terrain.py
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import matplotlib.pyplot as plt
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import numpy as np
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import cv2 as cv
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import os
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import pyskyline
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import pyskyline.localization
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FILE = 'terrain'
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SIZE = 256
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X = SIZE//2
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Y = SIZE//2
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if __name__ == '__main__':
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if os.path.isfile(f'{FILE}_{SIZE}.npz'):
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print("Save detected, loading ...")
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terrain = pyskyline.Terrain.load(f'{FILE}_{SIZE}')
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else:
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print("No save detected, generating new terrain ...")
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terrain = pyskyline.Terrain.generate(size=SIZE)
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terrain.compute_all_skylines()
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terrain.save(f'{FILE}_{SIZE}')
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print(f"Done, terrain saved as {FILE}_{SIZE}.npz")
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# Output elevation map
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cv.imwrite('elevation_map.jpg', terrain.dem.elevation)
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# Output color map
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cv.imwrite('color_map.jpg', terrain.dem.color)
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# Ouput field of view visualization
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cv.imwrite('fov.jpg', terrain.compute_fov(X, Y))
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# Ouput skyline
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skyline = terrain.compute_skyline(X, Y)
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plt.figure()
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plt.grid(False)
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plt.plot(np.arange(-180,180,360/256),skyline)
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plt.title('Skyline')
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plt.savefig('skyline.svg')
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# Generate heatmap
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skyline = np.roll(skyline, 8) # Add heading error
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skyline += np.random.normal(0,0.5, 256) # Add random noise
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mosse_correlation = pyskyline.MosseCorrelation(terrain, skyline)
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scoremap = mosse_correlation.generate_scoremap()
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plt.figure()
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plt.grid(False)
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fig = plt.imshow(scoremap)
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plt.title('Score map')
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plt.colorbar(fig)
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plt.savefig('scoremap.svg')
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"""
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from .digital_map import DigitalMap
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Copyright (C) 2024 University of South Brittany, Lab-STICC UMR 6285 All Rights Reserved.
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from .raycast import bresenham_line, get_highest_angle
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Licensed under the Apache License, Version 2.0 (the "License");
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you may not use this file except in compliance with the License.
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You may obtain a copy of the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the License is distributed on an "AS IS" BASIS,
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WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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See the License for the specific language governing permissions and
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limitations under the License.
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"""
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from .raycast import bresenham_line
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from .terrain import Terrain
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from .terrain import Terrain
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from .localization.mosse_correlation import MosseCorrelation
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src/pyskyline/digital_map.py
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src/pyskyline/digital_map.py
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import os
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import numpy as np
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import cv2 as cv
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import perlin_numpy as perlin
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class DigitalMap:
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DEFAULT_MASK = os.path.dirname(__file__) + '/../../resources/mask.jpg'
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DEFAULT_LAYERS = {
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-1 : (169, 166, 97), # Water
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18 : (175, 214, 238), # Sand
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36 : ( 34, 139, 34), # Grass
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82 : ( 20, 100, 20) # Tree
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}
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def __init__(self, seed:int, size:int, height:float, scale:float) -> None:
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self.height = height
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self.scale = scale
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self.seed = seed
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self.size = size
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self.elevation : 'np.ndarray|None' = None
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self.color : 'np.ndarray|None' = None
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def generate_elevation_map(self, mask_path:str) -> None:
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""" Generate grayscale elevation map from 2D perlin noise
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Args:
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mask_path (str): Terrain grayscale mask path.
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"""
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np.random.seed(self.seed)
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perlin_noise = perlin.generate_fractal_noise_2d(
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shape = (512,)*2,
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res = (2**3,)*2,
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octaves = 5
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)
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# Set noise in [0;1]
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p_min = np.min(perlin_noise)
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p_max = np.max(perlin_noise)
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perlin_noise = (perlin_noise - p_min) / (p_max - p_min)
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if self.size != 512:
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perlin_noise = cv.resize(perlin_noise, (self.size,)*2, interpolation=cv.INTER_CUBIC)
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# Open and rescale mask
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mask = cv.imread(mask_path, cv.IMREAD_GRAYSCALE)
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mask = cv.resize(mask, (self.size,)*2, interpolation=cv.INTER_CUBIC)
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OCEAN_HEIGHT = 30
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elevation_map = perlin_noise * mask
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elevation_map = np.clip(elevation_map, OCEAN_HEIGHT, 255)
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elevation_map = (elevation_map-OCEAN_HEIGHT) / (255-OCEAN_HEIGHT) * 255
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self.elevation = elevation_map.astype(dtype=np.uint8)
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def generate_color_map(self, layers:'dict|None'=None) -> None:
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""" Generate RGB colored map based on elevation map.
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Args:
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layers (dict): Layer dictionary where the key is the height and value the color in BGR.
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"""
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if layers is None:
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layers = self.DEFAULT_LAYERS
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color_map = np.full((self.size, self.size, 3), layers[-1], dtype=np.uint8)
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for height, color in list(layers.items())[1:]:
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mask = self.elevation > height
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color_map[mask] = color
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self.color = color_map
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@staticmethod
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def generate(seed:int, size:int, height:float, scale:float, mask_path:str=DEFAULT_MASK) -> 'DigitalMap':
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dem = DigitalMap(seed, size, height, scale)
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dem.generate_elevation_map(mask_path)
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dem.generate_color_map()
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return dem
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36
src/pyskyline/localization/localizator.py
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src/pyskyline/localization/localizator.py
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import numpy as np
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import cv2 as cv
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from multiprocessing import Pool, cpu_count
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from ..terrain import Terrain
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class Localizator:
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def __init__(self, terrain:Terrain, skyline:np.ndarray) -> None:
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self.terrain = terrain
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self.skyline = skyline
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def _compute_score_mp(self, func:callable, args:any, print_progress:bool=True):
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if print_progress:
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import rich.progress as rp
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progress_bar = rp.Progress(
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*rp.Progress.get_default_columns(),
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rp.TimeElapsedColumn(),
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rp.MofNCompleteColumn()
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)
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task = progress_bar.add_task('Compute heatmap', total=len(args))
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progress_bar.start()
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score_map = (self.terrain.dem.elevation != 0).astype(np.float16) * -1
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with Pool(processes=cpu_count()) as pool:
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results = pool.imap(func, args)
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for x, y, score in results:
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score_map[y, x] = np.clip(score, -65000, 65000)
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progress_bar.advance(task, 1)
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if print_progress:
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progress_bar.stop()
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return score_map
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def generate_scoremap(self):
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raise NotImplementedError()
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from scipy.fft import fft, ifft
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from scipy.fft import fft, ifft
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from scipy.signal import gaussian
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from scipy.signal import gaussian
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g = gaussian(256, std=2.25,sym=True)
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from ..terrain import Terrain
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G = fft(g)
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from .localizator import Localizator
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def compute_score(F : np.ndarray, h : np.ndarray) -> float:
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def compute_score(args) -> float:
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""" Compute the correlation score of the two skyline based on a MOSSE correlation filter.
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x, y, F, H, G = args
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Args:
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F (np.ndarray): Real skyline in fourier domain.
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h (np.ndarray): Simulated skyline in time domain.
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Returns:
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float: Correlation score, higher is the score higher the correlation is.
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"""
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H = fft(h)
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r = abs(ifft(H*G/F))
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r = abs(ifft(H*G/F))
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shift = np.argmax(r)
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shift = np.argmax(r)
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peak = r[shift]
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peak = r[shift]
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r[shift-5:shift+5] = 0
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r[shift-5:shift+5] = 0
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score = peak/math.sqrt(np.sum(np.power(r,2)))
|
score = peak/math.sqrt(np.sum(np.power(r,2)))
|
||||||
return math.log(score)
|
return x, y, score
|
||||||
|
|
||||||
|
class MosseCorrelation(Localizator):
|
||||||
|
def __init__(self, terrain: Terrain, skyline: np.ndarray) -> None:
|
||||||
|
super().__init__(terrain, skyline)
|
||||||
|
self.F = fft(skyline)
|
||||||
|
self.G = fft(gaussian(skyline.shape[0], std=2.25,sym=True))
|
||||||
|
|
||||||
|
def generate_scoremap(self, ray_dist:float=1000.0):
|
||||||
|
ray_count = self.F.shape[0]
|
||||||
|
args = [(
|
||||||
|
x,
|
||||||
|
y,
|
||||||
|
self.F,
|
||||||
|
fft(self.terrain.compute_skyline(x,y,ray_count,ray_dist)),
|
||||||
|
self.G
|
||||||
|
) for x in range(self.terrain.dem.size) for y in range(self.terrain.dem.size) if self.terrain.dem.elevation[y,x] == 0]
|
||||||
|
scoremap = self._compute_score_mp(compute_score, args)
|
||||||
|
scoremap = (scoremap-np.min(scoremap)) / (np.max(scoremap)-np.min(scoremap))
|
||||||
|
return scoremap
|
|
@ -1,22 +1,8 @@
|
||||||
#!/usr/bin/env python
|
|
||||||
|
|
||||||
"""
|
|
||||||
Copyright (C) 2024 University of South Brittany, Lab-STICC UMR 6285 All Rights Reserved.
|
|
||||||
|
|
||||||
Licensed under the Apache License, Version 2.0 (the "License");
|
|
||||||
you may not use this file except in compliance with the License.
|
|
||||||
You may obtain a copy of the License at
|
|
||||||
|
|
||||||
http://www.apache.org/licenses/LICENSE-2.0
|
|
||||||
|
|
||||||
Unless required by applicable law or agreed to in writing, software
|
|
||||||
distributed under the License is distributed on an "AS IS" BASIS,
|
|
||||||
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
|
|
||||||
See the License for the specific language governing permissions and
|
|
||||||
limitations under the License.
|
|
||||||
"""
|
|
||||||
|
|
||||||
import numpy as np
|
import numpy as np
|
||||||
|
import cv2 as cv
|
||||||
|
import math
|
||||||
|
|
||||||
|
from .digital_map import DigitalMap
|
||||||
|
|
||||||
def bresenham_line(x:int, y:int, dist:float, angle:float, limit:int) -> list:
|
def bresenham_line(x:int, y:int, dist:float, angle:float, limit:int) -> list:
|
||||||
"""Generate list of points of all grid cell where raycast hit.
|
"""Generate list of points of all grid cell where raycast hit.
|
||||||
|
@ -42,7 +28,7 @@ def bresenham_line(x:int, y:int, dist:float, angle:float, limit:int) -> list:
|
||||||
sy = 1 if y < y1 else -1
|
sy = 1 if y < y1 else -1
|
||||||
error = dx + dy
|
error = dx + dy
|
||||||
|
|
||||||
while (x != x1 and y != y1) and (0 <= x < limit and 0 <= y < limit):
|
while (x != x1 or y != y1) and (0 <= x < limit and 0 <= y < limit):
|
||||||
points.append((x,y))
|
points.append((x,y))
|
||||||
|
|
||||||
e2 = 2 * error
|
e2 = 2 * error
|
||||||
|
@ -53,5 +39,75 @@ def bresenham_line(x:int, y:int, dist:float, angle:float, limit:int) -> list:
|
||||||
error += dx
|
error += dx
|
||||||
y += sy
|
y += sy
|
||||||
|
|
||||||
|
|
||||||
return points
|
return points
|
||||||
|
|
||||||
|
def get_highest_angle(points:list, dem:DigitalMap) -> tuple:
|
||||||
|
m_height = 0
|
||||||
|
m_angle = 0
|
||||||
|
m_pos = points[-1]
|
||||||
|
|
||||||
|
for x, y in points[1:]:
|
||||||
|
height = dem.elevation[y,x]
|
||||||
|
if height > m_height:
|
||||||
|
m_height = height
|
||||||
|
dist = math.sqrt((points[0][0]-x)**2+(points[0][1]-y)**2) * dem.scale
|
||||||
|
angle = np.arctan((height * dem.height/255)/dist)
|
||||||
|
if angle >= m_angle:
|
||||||
|
m_angle = angle
|
||||||
|
m_pos = (x,y)
|
||||||
|
|
||||||
|
return np.rad2deg(m_angle), m_pos
|
||||||
|
|
||||||
|
def mp_compute_skyline(args:tuple) -> tuple:
|
||||||
|
dem, x, y, ray_count, ray_dist = args
|
||||||
|
return (x,y,compute_skyline(dem,x,y,ray_count,ray_dist))
|
||||||
|
|
||||||
|
def compute_skyline(dem:DigitalMap, x:int, y:int, ray_count:int, ray_dist:float) -> np.ndarray:
|
||||||
|
"""_summary_
|
||||||
|
|
||||||
|
Args:
|
||||||
|
x (int): X coordinate
|
||||||
|
y (int): Y coordinate
|
||||||
|
ray_count (int, optional): Raycast count. Defaults to 256.
|
||||||
|
ray_dist (float, optional): Raycast distance in meter. Defaults to 1000.0.
|
||||||
|
|
||||||
|
Returns:
|
||||||
|
np.ndarray: skyline array.
|
||||||
|
"""
|
||||||
|
ray_step = 2 * np.pi / (ray_count-1)
|
||||||
|
line = np.zeros((ray_count), dtype=np.float16)
|
||||||
|
|
||||||
|
for i in range(ray_count):
|
||||||
|
points = bresenham_line(x, y, ray_dist/dem.scale, ray_step*i, dem.size)
|
||||||
|
angle, _ = get_highest_angle(points, dem)
|
||||||
|
line[i] = angle
|
||||||
|
|
||||||
|
return line
|
||||||
|
|
||||||
|
def compute_fov(dem:DigitalMap, x:int, y:int, ray_count:int=256, ray_dist:float=1000.0) -> np.ndarray:
|
||||||
|
"""_summary_
|
||||||
|
|
||||||
|
Args:
|
||||||
|
x (int): X coordinate
|
||||||
|
y (int): Y coordinate
|
||||||
|
ray_count (int, optional): Raycast count. Defaults to 256.
|
||||||
|
ray_dist (float, optional): Raycast distance in meter. Defaults to 1000.0.
|
||||||
|
|
||||||
|
Returns:
|
||||||
|
np.ndarray: skyline array.
|
||||||
|
"""
|
||||||
|
ray_step = 2 * np.pi / (ray_count-1)
|
||||||
|
output = np.copy(dem.color)
|
||||||
|
|
||||||
|
output = cv.circle(output, (x,y), 3, (255,125,0),-1)
|
||||||
|
last_pos = None
|
||||||
|
|
||||||
|
for i in range(ray_count):
|
||||||
|
points = bresenham_line(x, y, ray_dist/dem.scale, ray_step*i, dem.size)
|
||||||
|
_, pos = get_highest_angle(points, dem)
|
||||||
|
|
||||||
|
if last_pos is not None:
|
||||||
|
output = cv.line(output,last_pos,pos,(0,0,255),2)
|
||||||
|
last_pos = pos
|
||||||
|
|
||||||
|
return output
|
|
@ -1,98 +1,37 @@
|
||||||
#!/usr/bin/env python
|
from multiprocessing import Pool, cpu_count
|
||||||
|
|
||||||
"""
|
|
||||||
Copyright (C) 2024 University of South Brittany, Lab-STICC UMR 6285 All Rights Reserved.
|
|
||||||
|
|
||||||
Licensed under the Apache License, Version 2.0 (the "License");
|
|
||||||
you may not use this file except in compliance with the License.
|
|
||||||
You may obtain a copy of the License at
|
|
||||||
|
|
||||||
http://www.apache.org/licenses/LICENSE-2.0
|
|
||||||
|
|
||||||
Unless required by applicable law or agreed to in writing, software
|
|
||||||
distributed under the License is distributed on an "AS IS" BASIS,
|
|
||||||
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
|
|
||||||
See the License for the specific language governing permissions and
|
|
||||||
limitations under the License.
|
|
||||||
"""
|
|
||||||
|
|
||||||
import os
|
|
||||||
import math
|
|
||||||
import numpy as np
|
import numpy as np
|
||||||
import cv2 as cv
|
import cv2 as cv
|
||||||
import perlin_numpy as perlin
|
from .digital_map import DigitalMap
|
||||||
from .raycast import bresenham_line
|
from . import raycast
|
||||||
|
|
||||||
print(__file__)
|
|
||||||
|
|
||||||
class Terrain:
|
class Terrain:
|
||||||
DEFAULT_MASK = os.path.dirname(__file__) + '/../../resources/mask.jpg'
|
def __init__(self, dem:DigitalMap) -> None:
|
||||||
DEFAULT_RAYCOUNT = 256
|
self.dem = dem
|
||||||
DEFAULT_RAYDIST = 1000.0
|
self.skylines = {}
|
||||||
DEFAULT_LAYERS = {
|
|
||||||
-1 : (169, 166, 97), # Water
|
|
||||||
18 : (175, 214, 238), # Sand
|
|
||||||
36 : ( 34, 139, 34), # Grass
|
|
||||||
82 : ( 20, 100, 20) # Tree
|
|
||||||
}
|
|
||||||
|
|
||||||
def __init__(self, seed:int, size:int, height:float, scale:float) -> None:
|
def compute_all_skylines(self, ray_count:int=256, ray_dist:float=1000.0, print_progress:bool=True):
|
||||||
self.seed = seed
|
args = [(self.dem, x, y, ray_count, ray_dist) for x in range(self.dem.size) for y in range(self.dem.size) if self.dem.elevation[y,x] == 0]
|
||||||
self.size = size
|
|
||||||
self.height = height
|
|
||||||
self.scale = scale
|
|
||||||
self.elevation_map = None
|
|
||||||
self.color_map = None
|
|
||||||
self.skylines = None
|
|
||||||
|
|
||||||
def generate_elevation_map(self, mask_path:str) -> None:
|
if print_progress:
|
||||||
""" Generate grayscale elevation map from 2D perlin noise
|
import rich.progress as rp
|
||||||
|
progress_bar = rp.Progress(
|
||||||
|
*rp.Progress.get_default_columns(),
|
||||||
|
rp.TimeElapsedColumn(),
|
||||||
|
rp.MofNCompleteColumn()
|
||||||
|
)
|
||||||
|
task = progress_bar.add_task('Compute skylines', total=len(args))
|
||||||
|
progress_bar.start()
|
||||||
|
|
||||||
Args:
|
with Pool(processes=cpu_count()) as pool:
|
||||||
mask_path (str): Terrain grayscale mask path.
|
results = pool.imap(raycast.mp_compute_skyline, args)
|
||||||
"""
|
for x, y, skyline in results:
|
||||||
np.random.seed(self.seed)
|
self.skylines[(x,y)] = skyline
|
||||||
perlin_noise = perlin.generate_fractal_noise_2d(
|
progress_bar.advance(task, 1)
|
||||||
shape = (512,)*2,
|
|
||||||
res = (2**3,)*2,
|
|
||||||
octaves = 5
|
|
||||||
)
|
|
||||||
|
|
||||||
# Set noise in [0;1]
|
if print_progress:
|
||||||
p_min = np.min(perlin_noise)
|
progress_bar.stop()
|
||||||
p_max = np.max(perlin_noise)
|
|
||||||
perlin_noise = (perlin_noise - p_min) / (p_max - p_min)
|
|
||||||
|
|
||||||
if self.size != 512:
|
def compute_skyline(self, x:int, y:int, ray_count:int=256, ray_dist:float=1000.0):
|
||||||
perlin_noise = cv.resize(perlin_noise, (self.size,)*2, interpolation=cv.INTER_CUBIC)
|
|
||||||
|
|
||||||
# Open and rescale mask
|
|
||||||
mask = cv.imread(mask_path, cv.IMREAD_GRAYSCALE)
|
|
||||||
mask = cv.resize(mask, (self.size,)*2, interpolation=cv.INTER_CUBIC)
|
|
||||||
|
|
||||||
elevation_map = perlin_noise * mask
|
|
||||||
|
|
||||||
self.elevation_map = elevation_map.astype(dtype=np.uint8)
|
|
||||||
|
|
||||||
def generate_colored_map(self, layers:'dict|None'=None) -> None:
|
|
||||||
""" Generate RGB colored map based on elevation map.
|
|
||||||
|
|
||||||
Args:
|
|
||||||
layers (dict): Layer dictionary where the key is the height and value the color in BGR.
|
|
||||||
"""
|
|
||||||
if layers is None:
|
|
||||||
layers = self.DEFAULT_LAYERS
|
|
||||||
|
|
||||||
h,w = self.elevation_map.shape
|
|
||||||
color_map = np.full((h,w,3), layers[-1], dtype=np.uint8)
|
|
||||||
|
|
||||||
for height, color in list(layers.items())[1:]:
|
|
||||||
mask = self.elevation_map > height
|
|
||||||
color_map[mask] = color
|
|
||||||
|
|
||||||
self.color_map = cv.cvtColor(color_map, cv.COLOR_BGR2RGB)
|
|
||||||
|
|
||||||
def compute_skyline(self, x:int, y:int, ray_count:int=256, ray_dist:float=1000.0) -> np.ndarray:
|
|
||||||
"""_summary_
|
"""_summary_
|
||||||
|
|
||||||
Args:
|
Args:
|
||||||
|
@ -104,30 +43,55 @@ class Terrain:
|
||||||
Returns:
|
Returns:
|
||||||
np.ndarray: skyline array.
|
np.ndarray: skyline array.
|
||||||
"""
|
"""
|
||||||
ray_step = 2 * np.pi / (ray_count-1)
|
if (x,y) not in self.skylines:
|
||||||
line = np.zeros((ray_count), dtype=np.float16)
|
self.skylines[(x,y)] = raycast.compute_skyline(self.dem, x, y, ray_count, ray_dist)
|
||||||
|
return self.skylines[(x,y)]
|
||||||
|
|
||||||
for i in range(ray_count):
|
def compute_fov(self, x:int, y:int, ray_count:int=256, ray_dist:float=1000.0):
|
||||||
max_height = -10
|
"""_summary_
|
||||||
max_v_angle = 0
|
|
||||||
points = bresenham_line(x, y, ray_dist/self.scale, ray_step*i, self.size)
|
|
||||||
for x0, y0 in points:
|
|
||||||
height = self.elevation_map[y0,x0]
|
|
||||||
if height > max_height:
|
|
||||||
max_height = height
|
|
||||||
dist = math.sqrt((x0-x)**2+(y0-y)**2) * self.scale
|
|
||||||
if dist != 0.0:
|
|
||||||
v_angle = np.arctan((height * self.height/255)/dist)
|
|
||||||
if v_angle > max_v_angle:
|
|
||||||
max_v_angle = v_angle
|
|
||||||
|
|
||||||
line[i] = np.rad2deg(max_v_angle)
|
Args:
|
||||||
|
x (int): X coordinate
|
||||||
|
y (int): Y coordinate
|
||||||
|
ray_count (int, optional): Raycast count. Defaults to 256.
|
||||||
|
ray_dist (float, optional): Raycast distance in meter. Defaults to 1000.0.
|
||||||
|
|
||||||
return line
|
Returns:
|
||||||
|
np.ndarray: skyline array.
|
||||||
|
"""
|
||||||
|
return raycast.compute_fov(self.dem, x, y, ray_count, ray_dist)
|
||||||
|
|
||||||
|
def save(self, file:str):
|
||||||
|
np.savez_compressed(f'{file}.npz',
|
||||||
|
size = self.dem.size,
|
||||||
|
seed = self.dem.seed,
|
||||||
|
height = self.dem.height,
|
||||||
|
scale = self.dem.scale,
|
||||||
|
elevation_map = self.dem.elevation,
|
||||||
|
skylines = self.skylines
|
||||||
|
)
|
||||||
|
|
||||||
|
@staticmethod
|
||||||
|
def load(file:str) -> 'Terrain':
|
||||||
|
if not file.endswith('.npz'):
|
||||||
|
file += ".npz"
|
||||||
|
save = np.load(file,allow_pickle=True)
|
||||||
|
dem = DigitalMap(
|
||||||
|
seed = save['seed'],
|
||||||
|
size = save['size'],
|
||||||
|
height = save['height'],
|
||||||
|
scale = save['scale']
|
||||||
|
)
|
||||||
|
dem.elevation = save.get('elevation_map')
|
||||||
|
dem.generate_color_map()
|
||||||
|
terrain = Terrain(dem)
|
||||||
|
terrain.skylines = save['skylines'].item()
|
||||||
|
|
||||||
|
return terrain
|
||||||
|
|
||||||
@staticmethod
|
@staticmethod
|
||||||
def generate(seed:int=0x7B16, size:int=512, height:float=25.0, scale:float=1.0,
|
def generate(seed:int=0x7B16, size:int=512, height:float=25.0, scale:float=1.0,
|
||||||
mask_path:str=DEFAULT_MASK) -> 'Terrain':
|
mask_path:str=DigitalMap.DEFAULT_MASK) -> 'Terrain':
|
||||||
""" Generate a procedural terrain using seed and mask, and precompute all horizon lines
|
""" Generate a procedural terrain using seed and mask, and precompute all horizon lines
|
||||||
|
|
||||||
Args:
|
Args:
|
||||||
|
@ -140,8 +104,7 @@ class Terrain:
|
||||||
Returns:
|
Returns:
|
||||||
Terrain: _description_
|
Terrain: _description_
|
||||||
"""
|
"""
|
||||||
terrain = Terrain(seed,size,height,scale)
|
dem = DigitalMap.generate(seed, size, height, scale, mask_path)
|
||||||
terrain.generate_elevation_map(mask_path)
|
terrain = Terrain(dem)
|
||||||
terrain.generate_colored_map()
|
|
||||||
|
|
||||||
return terrain
|
return terrain
|
||||||
|
|
|
@ -1,13 +0,0 @@
|
||||||
import matplotlib.pyplot as plt
|
|
||||||
import numpy as np
|
|
||||||
|
|
||||||
import pyskyline
|
|
||||||
|
|
||||||
terrain = pyskyline.Terrain.generate()
|
|
||||||
h = terrain.compute_skyline(330,330,360)
|
|
||||||
|
|
||||||
plt.figure()
|
|
||||||
plt.imshow(terrain.elevation_map)
|
|
||||||
plt.figure()
|
|
||||||
plt.plot(np.arange(0,360,360/h.shape[0]), h)
|
|
||||||
plt.show()
|
|
Loading…
Reference in a new issue