else/TKCube/tkcube.py
2015-08-02 21:28:40 -07:00

117 lines
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3.9 KiB
Python

import copy
import math
import random
import tkinter
class TKCube:
def __init__(self):
self.t = tkinter.Tk()
self.FACES = [
[[2, 2, 1], [2, -2, 1], [-2, -2, 1], [-2, 2, 1]],
[[2, -2, 1], [-2, -2, -1], [-2, 2, -1], [2, 2, -1]],
[[-2, -2, 1], [2, -2, 1], [2, -2, -1], [-2, -2, -1]],
[[-2, 2, 1], [2, 2, 1], [2, 2, -1], [-2, 2, -1]],
[[-2, -2, -1], [-2, 2, -1], [-2, 2, 1], [-2, -2, -1]],
[[2, -2, 1], [2, 2, 1], [2, 2, -1], [2, -2, -1]],
]
self.INFLATE_SCALE = 8
self.c = tkinter.Canvas(self.t, width=600, height=600, bg='#444')
self.c.pack(fill='both', expand=True)
self.t.bind('<Return>', self.render)
self.is_mouse_down = False
self.prev_mouse_x = None
self.prev_mouse_y = None
self.t.bind('<ButtonPress-1>', self.mouse_down)
self.t.bind('<ButtonRelease-1>', self.mouse_up)
self.t.bind('<Motion>', self.mouse_motion)
self.t.bind('<Up>', lambda event: self.arbitrarymove(0, -1))
self.t.bind('<Down>', lambda event: self.arbitrarymove(0, 1))
self.t.bind('<Left>', lambda event: self.arbitrarymove(-1, 0))
self.t.bind('<Right>', lambda event: self.arbitrarymove(1, 0))
self.render()
self.t.mainloop()
def arbitrarymove(self, deltax, deltay):
for face in self.FACES:
for point in face:
point[0] += deltax
point[1] += deltay
self.render()
def mouse_down(self, event):
self.is_mouse_down = True
def mouse_up(self, event):
self.is_mouse_down = False
def mouse_motion(self, event):
if not self.is_mouse_down:
return
if self.prev_mouse_x is None:
self.prev_mouse_x = event.x
self.prev_mouse_y = event.y
distance = math.sqrt( ((event.x - self.prev_mouse_x) ** 2) + ((event.y - self.prev_mouse_y) ** 2) )
self.prev_mouse_x = event.x
self.prev_mouse_y = event.y
print(distance)
def center_of_square(self, face):
x = 0; y = 0; z = 0
for point in face:
x += point[0]
y += point[1]
z += point[2]
return [x/4, y/4, z/4]
def plot_point_screen(self, x, y, diameter=4):
radius = diameter / 2
x1 = x - radius
y1 = y - radius
x2 = x + radius
y2 = y + radius
self.c.create_oval(x1, y1, x2, y2, fill='#000')
def render(self, *event):
self.c.delete('all')
rendered_faces = copy.deepcopy(self.FACES)
# Sort by depth from camera
# The sort key is the z value of the coordinate
# in the center of the face
rendered_faces.sort(key=lambda face: self.center_of_square(face)[2])
canvas_width_half = self.c.winfo_width() / 2
canvas_height_half = self.c.winfo_height() / 2
highest_z = max([max([point[2] for point in face]) for face in rendered_faces])
for face in self.FACES:
for point in face:
x = point[0]
y = point[1]
z = point[2]
# Push everything away from the camera so all z are <= 0
z -= highest_z
# Create vanishing point.
distance_camera = math.sqrt((x**2) + (y**2) + (z**2))
#if z != 0:
# factor = (abs(z) ** 0.2) - 1
# print(factor)
#else:
# factor = 0
x += x * factor
y += y * factor
# Inflate for display
x *= self.INFLATE_SCALE
y *= self.INFLATE_SCALE
z *= self.INFLATE_SCALE
# Shift the coordinates into the screen
x += canvas_width_half
y += canvas_height_half
self.plot_point_screen(x, y)
#print(rendered_faces)
t = TKCube()