def _get_pattern_at_shape(self, colour, pattern, object, px, py, pz):
pw = Point(float(px), float(py), float(pz))
# Point is in world space, first transform to object space
po = getattr(world, object).inverse_transform * pw
# Pattern will handle the transform from object to pattern space
c = getattr(world, pattern).pattern_at(po)
setattr(world, colour, c)
def _ray_origin_equals_point(self, name, x, y, z):
test_point = Point(float(x), float(y), float(z))
print("\nExpected:")
print(test_point)
print("\nGot:")
print(getattr(world, name).origin)
assert getattr(world, name).origin == test_point
def _position_equals_point(self, name, t, px, py, pz):
test_point = Point(float(px), float(py), float(pz))
print("\nExpected:")
print(test_point)
print("\nGot:")
print(getattr(world, name).position(float(t)))
assert getattr(world, name).position(float(t)) == test_point
def _check_saved_ray_origin(self, name, px, py, pz):
test_point = Point(float(px), float(py), float(pz))
point = getattr(world, name).saved_ray.origin
print("\nExpected:")
print(test_point)
print("\nGot:")
print(point)
assert point == test_point
def _compare_point_by_value(self, name, x, y, z):
test_value = Point(float(x), float(y), float(z))
value = getattr(world, name).point
print("\nExpected:")
print(test_value)
print("\nGot:")
print(value)
assert value == test_value
def __mupltiply_matrix_point(self, name1, name2, x, y, z):
test_point = Point(float(x), float(y), float(z))
print("\nTransformation matrix is:")
print(getattr(world, name1))
print("\nExpected:")
print(test_point)
print("\nGot:")
print(getattr(world, name1) * getattr(world, name2))
assert getattr(world, name1) * getattr(world, name2) == test_point
def _check_pattern_by_colour(self, pattern, px, py, pz, r, g, b):
pat = getattr(world, pattern)
pos = Point(float(px), float(py), float(pz))
tc = Colour(float(r), float(g), float(b))
c = pat.pattern(pos)
print("\nExpected:")
print(tc)
print("\nGot:")
print(c)
assert c == tc
def _check_pattern_by_name(self, pattern, px, py, pz, col):
pat = getattr(world, pattern)
pos = Point(float(px), float(py), float(pz))
tc = getattr(world, col)
c = pat.pattern(pos)
print("\nExpected:")
print(tc)
print("\nGot:")
print(c)
assert c == tc
def _check_stripe_at(self, name, px, py, pz, colour):
p = Point(float(px), float(py), float(pz))
c = getattr(world, colour)
pat = getattr(world, name)
col = pat.pattern_at(p)
print("\nExpected:")
print(c)
print("\nGot:")
print(col)
assert col == c
def pattern(self, point):
# Incoming point has already been transformed into pattern space
# by the parent Pattern class
# Shift x, y and z by an amount of noise before passing to the
# inner pattern.
x = point.x
y = point.y
z = point.z
dx = self.noise.eval2d(y, z) * self.size
dy = self.noise.eval2d(x, z) * self.size
dz = self.noise.eval2d(x, y) * self.size
pp = Point(x + dx, y + dy, z + dz)
# Return the simple average of colour returned by the two inner
# patterns
return self.a.pattern_at(pp)
def _local_normal_at(self, name1, name2, px, py, pz):
p = Point(float(px), float(py), float(pz))
o = getattr(world, name2)
setattr(world, name1, o.local_normal_at(p))
#!/usr/bin/env python
from Tuple4 import Point, Colour
import Canvas
import math
def plot(canvas, point, colour):
x = int((canvas.width / 2) + round(point.x))
y = int((canvas.height / 2) - round(point.y))
c.write_pixel(x, y, colour)
def plot_cross(canvas, point, colour):
x = int((canvas.width / 2) + round(point.x))
y = int((canvas.height / 2) - round(point.y))
c.write_pixel(x, y, colour)
c.write_pixel(x + 1, y, colour)
c.write_pixel(x - 1, y, colour)
c.write_pixel(x, y + 1, colour)
c.write_pixel(x, y - 1, colour)
white = Colour(0.8, 0.8, 0.8)
c = Canvas.Canvas(600, 600)
p = Point(0, 250, 0)
for r in range(0, 12):
p2 = p.rotate_z(-r * math.pi / 6)
plot_cross(c, p2, white)
c.to_ppm_file("clock.ppm")
def _normal_at_point(self, name1, name2, x, y, z):
p = Point(float(x), float(y), float(z))
n = getattr(world, name2).normal_at(p)
setattr(world, name1, n)
def _point_light_by_number(self, name, x, y, z, r, g, b):
setattr(
world, name,
PointLight(Point(float(x), float(y), float(z)),
Colour(float(r), float(g), float(b))))
def _ray_from_values(self, name, px, py, pz, vx, vy, vz):
setattr(
world, name,
Ray(Point(float(px), float(py), float(pz)),
Vector(float(vx), float(vy), float(vz))))
