from math import sqrt, pow, pi
import Image
class Vector( object ):
def __init__(self,x,y,z):
self.x = x
self.y = y
self.z = z
def dot(self, b):
return self.x*b.x + self.y*b.y + self.z*b.z
def cross(self, b):
return (self.y*b.z-self.z*b.y, self.z*b.x-self.x*b.z, self.x*b.y-self.y*b.x)
def magnitude(self):
return sqrt(self.x**2+self.y**2+self.z**2)
def normal(self):
mag = self.magnitude()
return Vector(self.x/mag,self.y/mag,self.z/mag)
def __add__(self, b):
return Vector(self.x + b.x, self.y+b.y, self.z+b.z)
def __sub__(self, b):
return Vector(self.x-b.x, self.y-b.y, self.z-b.z)
def __mul__(self, b):
assert type(b) == float or type(b) == int
return Vector(self.x*b, self.y*b, self.z*b)
class Sphere( object ):
def __init__(self, center, radius, color):
self.c = center
self.r = radius
self.col = color
def intersection(self, l):
q = l.d.dot(l.o - self.c)**2 - (l.o - self.c).dot(l.o - self.c) + self.r**2
if q < 0:
return Intersection( Vector(0,0,0), -1, Vector(0,0,0), self)
else:
d = -l.d.dot(l.o - self.c)
d1 = d - sqrt(q)
d2 = d + sqrt(q)
if 0 < d1 and ( d1 < d2 or d2 < 0):
return Intersection(l.o+l.d*d1, d1, self.normal(l.o+l.d*d1), self)
elif 0 < d2 and ( d2 < d1 or d1 < 0):
return Intersection(l.o+l.d*d2, d2, self.normal(l.o+l.d*d2), self)
else:
return Intersection( Vector(0,0,0), -1, Vector(0,0,0), self)
def normal(self, b):
return (b - self.c).normal()
class Plane( object ):
def __init__(self, point, normal, color):
self.n = normal
self.p = point
self.col = color
def intersection(self, l):
d = l.d.dot(self.n)
if d == 0:
return Intersection( vector(0,0,0), -1, vector(0,0,0), self)
else:
d = (self.p - l.o).dot(self.n) / d
return Intersection(l.o+l.d*d, d, self.n, self)
class Ray( object ):
def __init__(self, origin, direction):
self.o = origin
self.d = direction
class Intersection( object ):
def __init__(self, point, distance, normal, obj):
self.p = point
self.d = distance
self.n = normal
self.obj = obj
def testRay(ray, objects, ignore=None):
intersect = Intersection( Vector(0,0,0), -1, Vector(0,0,0), None)
for obj in objects:
if obj is not ignore:
currentIntersect = obj.intersection(ray)
if currentIntersect.d > 0 and intersect.d < 0:
intersect = currentIntersect
elif 0 < currentIntersect.d < intersect.d:
intersect = currentIntersect
return intersect
def trace(ray, objects, light, maxRecur):
if maxRecur < 0:
return (0,0,0)
intersect = testRay(ray, objects)
if intersect.d == -1:
col = vector(AMBIENT,AMBIENT,AMBIENT)
elif intersect.n.dot(light - intersect.p) < 0:
col = intersect.obj.col * AMBIENT
else:
lightRay = Ray(intersect.p, (light-intersect.p).normal())
if testRay(lightRay, objects, intersect.obj).d == -1:
lightIntensity = 1000.0/(4*pi*(light-intersect.p).magnitude()**2)
col = intersect.obj.col * max(intersect.n.normal().dot((light - intersect.p).normal()*lightIntensity), AMBIENT)
else:
col = intersect.obj.col * AMBIENT
return col
def gammaCorrection(color,factor):
return (int(pow(color.x/255.0,factor)*255),
int(pow(color.y/255.0,factor)*255),
int(pow(color.z/255.0,factor)*255))
AMBIENT = 0.1
GAMMA_CORRECTION = 1/2.2
objs = []
objs.append(Sphere( Vector(-2,0,-10), 2, Vector(0,255,0)))
objs.append(Sphere( Vector(2,0,-10), 3.5, Vector(255,0,0)))
objs.append(Sphere( Vector(0,-4,-10), 3, Vector(0,0,255)))
objs.append(Plane( Vector(0,0,-12), Vector(0,0,1), Vector(255,255,255)))
lightSource = Vector(0,10,0)
img = Image.new("RGB",(500,500))
cameraPos = Vector(0,0,20)
for x in range(500):
print x
for y in range(500):
ray = Ray( cameraPos, (Vector(x/50.0-5,y/50.0-5,0)-cameraPos).normal())
col = trace(ray, objs, lightSource, 10)
img.putpixel((x,499-y),gammaCorrection(col,GAMMA_CORRECTION))
img.save("trace.bmp","BMP")