forked from Pavel/labygui
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This is a modified version of the Python script for the TI-Planet and
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Planete Casio back to school 2020 contest.
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This modified version works with Python 3 under GNU Linux and MS Windows.
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The original code can be found at:
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https://tiplanet.org/forum/viewtopic.php?f=49&t=24276
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This script can be executed with the following command:
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python3 labygui.py
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from math import sin, cos, pi, sqrt, asin
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from tkinter import *
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laby_w, laby_h = 20, 12
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wl = [676499, 819210, 704161, 828804, 911396, 1010837, 772540, 600182, 526017, 803480, 756064, 701196, 1756736, 1376344, 1158834, 1315990, 1102792, 1323847, 1497194, 1810708, 1327018, 1094903, 1349813]
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zint = 2
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screen_w, screen_h = laby_w * 50 + 2, laby_h * 50 + 2
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zx, zy = (screen_w - zint) / laby_w, (screen_h - zint) / laby_h
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master = Tk()
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master.resizable(0, 0)
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index = 0
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path = [(0.0, 0.5)]
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def escape(event):
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global master
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master.quit()
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def add(event):
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global path, index
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if len(path) < 28:
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index += 1
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path.append((0.0, 0.5))
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aller_selon(path)
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def remove(event):
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global path, index
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if len(path) > 1:
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index -= 1
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path = path[:-1]
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aller_selon(path)
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def next(event):
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global path, index
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if index < len(path) - 1:
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index += 1
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aller_selon(path)
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def previous(event):
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global path, index
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if index > 0:
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index -= 1
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aller_selon(path)
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def left(event):
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global path, index
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path[index] = (round(path[index][0] + 0.1, 1), path[index][1])
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aller_selon(path)
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def right(event):
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global path, index
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path[index] = (round(path[index][0] - 0.1, 1), path[index][1])
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aller_selon(path)
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def up(event):
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global path, index
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path[index] = (path[index][0], round(path[index][1] + 0.1, 1))
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aller_selon(path)
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def down(event):
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global path, index
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if path[index][1] > 0:
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path[index] = (path[index][0], round(path[index][1] - 0.1, 1))
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aller_selon(path)
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def print_code(event):
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global path
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print('')
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print('path = %s' % path)
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print('')
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print('def chemin():')
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for i in range(len(path)):
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print(' a_gauche(%s)' % path[i][0])
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print(' avancer(%s)' % path[i][1])
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print('')
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master.bind('<Escape>', escape)
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master.bind('<Return>', add)
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master.bind('<Delete>', remove)
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master.bind('<Prior>', previous)
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master.bind('<Next>', next)
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master.bind('<Left>', left)
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master.bind('<Right>', right)
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master.bind('<Up>', up)
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master.bind('<Down>', down)
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master.bind('p', print_code)
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master.bind('P', print_code)
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canvas = Canvas(master, width = screen_w, height = screen_h + 68, bg = 'white')
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canvas.pack()
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def clean_screen():
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canvas.delete('all')
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def draw_rect(x, y, w, h, color):
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x += 1
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y += 1
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canvas.create_rectangle(x, y, x + w, y + h, fill = color, outline = '')
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def draw_line(x1, y1, x2, y2, color):
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canvas.create_line(x1 + 1, y1 + 1, x2 + 1, y2 + 1, fill = color, width = 2.0)
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def draw_help():
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help = 'change angle: Left/Right, change length: Up/Down, add/remove element: Enter/Delete, previous/next element: PgDn/PgUp, print code: P, exit: Esc'
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canvas.create_text(4, screen_h + 36, anchor = NW, text = help, fill = 'black')
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def draw_path():
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global path
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canvas.create_text(4, screen_h + 4, anchor = NW, text = '%s' % path[0:14], fill = 'black')
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canvas.create_text(4, screen_h + 20, anchor = NW, text = '%s' % path[14:28], fill = 'black')
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def draw_score(score):
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canvas.create_text(4, screen_h + 52, anchor = NW, text = 'score: %f' % score, fill = 'black')
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def fix_angle(a):
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return a * 2 * asin(1) / pi
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def cout(x):
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return len(str(round(abs(x)/1.,5)))
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def tourner(a):
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global state
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state[7] += a
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state[5] += 5 + cout(a)
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state[2] -= a
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def avancer(l, color):
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global state
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t = fix_angle(state[2])
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dx, dy = cos(t), sin(t)
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state[7] += l
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state[5] += 8 + cout(l)
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while(l > 0):
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state[3:5] = state[0:2]
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x, y = state[0] + dx/4, state[1] + dy/4
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ix, iy = int(x) - (x < 0), int(y) - (y < 0)
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drx, dry = ix - int(state[3]), iy - int(state[4])
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vw = lambda y, x: wl[y] & 2**x
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hw = lambda y, x: wl[y + laby_h] & 2**x
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tx = drx and (ix < 0 or ix >= laby_w or vw(iy - dry, laby_w - 2 - min(ix, ix - drx)))
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ty = dry and (iy < 0 or iy >= laby_h or hw(min(iy, iy - dry), laby_w - 1 - (ix - drx)))
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t = dx <= 0 or int(x) < laby_w - 1 or int(y) < laby_h - 1
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if t and tx or ty or (drx and dry and (t and tx or ty)) or (drx and dry and (t and vw(iy, laby_w - 2 - min(ix, ix - drx)) or hw(min(iy, iy - dry), laby_w - 1 - ix))):
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state[5] += 15
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return
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l -= .25
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state[6] += (state[6] < 200)
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state[0:2] = (x, y)
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draw_line(state[3] * zx, state[4] * zy, state[0] * zx, state[1] * zy, color)
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def aller_selon(path):
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global state
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state = [0, .5, 0, 0, .5, 0, 0, 0]
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clean_screen()
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for i in range(2):
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draw_rect(0, i * laby_h * zy, laby_w * zx + zint, zint, 'black')
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draw_rect(i * laby_w * zx, (not i) * zy, zint, (laby_h - 1) * zy, 'black')
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for y in range(2 * laby_h - 1):
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for z in range(laby_w - (y < laby_h)):
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if wl[y] & 2**z:
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x = laby_w - 1 - z
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if y < laby_h:
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draw_rect(x * zx, y * zy, zint, zy + zint, 'black')
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else:
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pass
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draw_rect(x * zx, (y - laby_h + 1) * zy, zx + zint, zint, 'black')
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for i in range(len(path)):
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tourner(path[i][0])
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if i == index:
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avancer(path[i][1], 'red')
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else:
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avancer(path[i][1], 'blue')
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state[5] += sin(fix_angle(state[7])) - state[6] // 2
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draw_help()
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draw_path()
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draw_score(state[5])
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aller_selon(path)
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if __name__== "__main__":
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master.mainloop()
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