# Intersection between bezier curve and a line segment

I am writing a game in Python (with pygame) that requires me to generate random but nice-looking "sea" for each new game. After a long search I settled on an algorithm that involves Bezier curves as defined in padlib.py. I now need to figure out when the curves generated by padlib intersect a line segment.

The brute force method would be to just use the set of approximating line segments produced by padlib to find the answer. However, I suspect that a better answer can be found analytically. I only have a few dozen spline segments - searching them should be faster than thousand of line segments.

A little search took me down this road: Bezier Curve -> Kochanek-Bartels Spline -> Cubic Hermite spline

On the last page, I found this function:

p(t) = h00(t)p0 + h10(t)m0 + h01(t)p1 + h11(t)m1

where p(t) is a actually a point (2-dimensional vector), hij(t) functions are cubic polynomials, p0, p1, m0 and m1 are points I can get from padlib code.

Now, I can see that the solution to my problem is p(t) = u + v * t1, where u and v are the end of my line segment.

However, working out the analytical solution is beyond me. Does anyone here know of an existing solution? Or can help me with solving the equations?

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would be nice if you show an involved part of your source code, because your question is too obscure –  psihodelia Nov 28 '09 at 21:10
The relevant code is mostly in padlib.py. And the math in Wikipedia articles is more relevant than the code. –  Arkadiy Nov 29 '09 at 0:26

As a rough outline, rotate and translate the system so that the line segment lies on the X axis. Now the y coordinate is a cubic function of the parameter t. Find the 'zeros' (the analytic formulae will be found in good math texts or wikipedia). Now evaluate the x coordinates corresponding to those zero points and test against your line segment.

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I've finally got to a working code to illustrate the method suggested by Mark Thornton. Below is the Python code for the intersection routine, together with pygame code to test it visually. The cubic roots solution can be written based on this question.

``````import pygame
from pygame.locals import *
import sys
import random
from math import sqrt, fabs, pow
from lines import X, Y
import itertools
import pygame
from pygame import draw, Color
from roots_detailed import cubicRoots

X = 0
Y = 0
for (x,y) in points:
X += x
Y += y
return (X,Y)

def diff_points(p2, p1):
# p2 - p1
return (X(p2)-X(p1), Y(p2)-Y(p1));

def scale_point(factor, p):
return (factor * X(p), factor*Y(p))

def between(v0, v, v1):
if v0 > v1: v0, v1 = v1, v0
return v >= v0 and v <= v1

# the point is guaranteed to be on the right line
def pointOnLineSegment(l1, l2, point):
return between(X(l1), X(point), X(l2)) and between(Y(l1), Y(point), Y(l2))

def rotate(x, y, R1, R2, R3, R4):
return (x*R1 + y*R2, x*R3 + y * R4);

def findIntersections(p0, p1, m0, m1, l1, l2):
# We're solving the equation of one segment of Kochanek-Bartels
# spline intersecting with a line segment
# The spline is described at http://en.wikipedia.org/wiki/Cubic_Hermite_spline
# The discussion on the adopted solution can be found at http://stackoverflow.com/questions/1813719/intersection-between-bezier-curve-and-a-line-segment
#
# The equation we're solving is
#
# h00(t) p0 + h10(t) m0 + h01(t) p1 + h11(t) m1 = u + v t1
#
# where
#
# h00(t) = 2t^3 - 3t^2 + 1
# h10(t) = t^3 - 2t^2 + t
# h01(t) = -2t^3 + 3t^2
# h11(t) = t^3 - t^2
# u = l1
# v = l2-l1

u = l1
v = diff_points(l2, l1);

# The first thing we do is to move u to the other side:
#
# h00(t) p0 + h10(t) m0 + h01(t) p1 + h11(t) m1 - u = v t1
#
# Then we're looking for matrix R that would turn (v t1) into
# ({|v|, 0} t1). This is rotation of coordinate system matrix,
# described at http://mathworld.wolfram.com/RotationMatrix.html
#
# R(h00(t) p0 + h10(t) m0 + h01(t) p1 + h11(t) m1 - u) = R(v t1) = {|v|, 0}t1
#
# We only care about R[1,0] and R[1,1] because it lets us solve
# the equation for y coordinate where y == 0 (intersecting the
# spline segment with the x axis of rotated coordinate
# system). I'll call R[1,0] = R3 and R[1,1] = R4 .

v_abs = sqrt(v[0] ** 2 + v[1] ** 2)
R1 =  X(v) / v_abs
R2 =  Y(v) / v_abs
R3 = -Y(v) / v_abs
R4 =  X(v) / v_abs

# The letters x and y are denoting x and y components of vectors
# p0, p1, m0, m1, and u.

p0x = p0[0]; p0y = p0[1]
p1x = p1[0]; p1y = p1[1]
m0x = m0[0]; m0y = m0[1]
m1x = m1[0]; m1y = m1[1]
ux = X(u); uy = Y(u)

#
#
#   R3(h00(t) p0x + h10(t) m0x + h01(t) p1x + h11(t) m1x - ux) +
# + R4(h00(t) p0y + h10(t) m0y + h01(t) p1y + h11(t) m1y - uy) = 0
#
# Opening all parentheses and simplifying for hxx we get:
#
#   h00(t) p0x R3 + h10(t) m0x R3 + h01(t) p1x R3 + h11(t) m1x R3 - ux R3 +
# + h00(t) p0y R4 + h10(t) m0y R4 + h01(t) p1y R4 + h11(t) m1y R4 - uy R4 = 0
#
#   h00(t) p0x R3 + h10(t) m0x R3 + h01(t) p1x R3 + h11(t) m1x R3 - ux R3 +
# + h00(t) p0y R4 + h10(t) m0y R4 + h01(t) p1y R4 + h11(t) m1y R4 - uy R4 = 0
#
#   (1)
#   h00(t) (p0x R3 + p0y R4) + h10(t) (m0x R3 + m0y R4) +
#   h01(t) (p1x R3 + p1y R4) + h11(t) (m1x R3 + m1y R4) - (ux R3 + uy R4) = 0
#
# We now introduce new substitution

K00 = p0x * R3 + p0y * R4
K10 = m0x * R3 + m0y * R4
K01 = p1x * R3 + p1y * R4
K11 = m1x * R3 + m1y * R4
U = ux * R3 + uy * R4

# Expressed in those terms, equation (1) above becomes
#
# h00(t) K00 + h10(t) K10 + h01(t) K01 + h11(t) K11 - U = 0
#
# We will now substitute the expressions for hxx(t) functions
#
# (2t^3 - 3t^2 + 1) K00 + (t^3 - 2t^2 + t) K10 + (-2t^3 + 3t^2) K01 + (t^3 - t^2) K11 - U = 0
#
#   2 K00 t^3 - 3 K00 t^2 + K00 +
# + K10 t^3 - 2 K10 t^2 + K10 t -
# - 2 K01 t^3 + 3 K01 t^2 +
# + K11 t^3  - K11 t^2 - U = 0
#
#   2 K00 t^3 - 3 K00 t^2 +    0t +  K00
# + K10   t^3 - 2 K10 t^2 + K10 t
# - 2 K01 t^3 + 3 K01 t^2
# +   K11 t^3 -   K11 t^2 +    0t -   U = 0
#
#  (2 K00 + K10 - 2K01 + K11) t^3
# +(-3 K00 - 2K10 + 3 K01 - K11) t^2
# + K10 t
# + K00 - U = 0
#
#
# (2 K00 + K10 - 2K01 + K11) t^3 + (-3 K00 - 2K10 + 3 K01 - K11) t^2 + K10 t + K00 - U = 0
#
# All we need now is to solwe a cubic equation
valuesOfT = cubicRoots((2 * K00 + K10 - 2 * K01 + K11),
(-3 * K00 - 2 * K10 + 3 * K01 - K11),
(K10),
K00 - U)
# We can then put the values of it into our original spline segment
# formula to find the potential intersection points.  Any point
# that's on original line segment is an intersection

def h00(t): return 2 * t**3 - 3 * t**2 + 1
def h10(t): return t**3 - 2 * t**2 + t
def h01(t): return -2 * t**3 + 3 * t**2
def h11(t): return t**3 - t**2

intersections = []
for t in valuesOfT:
if t < 0 or t > 1.0: continue
# point = h00(t) * p0 + h10(t) * m0 + h01(t) * p1 + h11(t) * m1
scale_point(h00(t), p0),
scale_point(h10(t), m0),
scale_point(h01(t), p1),
scale_point(h11(t), m1)
)

if pointOnLineSegment(l1, l2, point): intersections.append(point)

return intersections

def findIntersectionsManyCurves(p0_array, p1_array, m0_array, m1_array, u, v):
result = [];
for (p0, p1, m0, m1) in itertools.izip(p0_array, p1_array, m0_array, m1_array):
result.extend(findIntersections(p0, p1, m0, m1, u, v))
return result

def findIntersectionsManyCurvesManyLines(p0, p1, m0, m1, points):
result = [];

for (u,v) in itertools.izip(*[iter(points)]*2):
result.extend(findIntersectionsManyCurves(p0, p1, m0, m1, u, v))

return result

class EventsEmitter(object):
def __init__(self):
self.consumers = []

def emit(self, eventName, *params):
for method in self.consumers:
funcName = method.im_func.func_name if hasattr(method, "im_func") else method.func_name
if funcName == eventName:
method(*params)
def register(self, method):
self.consumers.append(method)

def unregister(self, method):
self.consumers.remove(method)

class BunchOfPointsModel(EventsEmitter):
def __init__(self):
EventsEmitter.__init__(self)
self.pts = []

def points(self):
return self.pts.__iter__()

def pointsSequence(self):
return tuple(self.pts)

def have(self, point):
return point in self.pts

self.pts.append(p)
self.emit("pointsChanged", p)

def replacePoint(self, oldP, newP):
idx = self.pts.index(oldP)
self.pts[idx] = newP
self.emit("pointsChanged", newP)

def removePoint(self, p):
self.point.remove(p)
self.emit("pointsChanged", p)

class BunchOfPointsCompositeModel(object):
def __init__(self, m1, m2):
self.m1 = m1
self.m2 = m2

def points(self):
return itertools.chain(self.m1.points(), self.m2.points())

def have(self, point):
return self.m1.have(point) or self.m2.have(point)

def replacePoint(self, oldP, newP):
if self.m1.have(oldP):
self.m1.replacePoint(oldP, newP)
else:
self.m2.replacePoint(oldP, newP)

def removePoint(self, p):
if self.m1.have(p):
self.m1.removePoint(p)
else:
self.m2.removePoint(p)

def register(self, method):
self.m1.register(method)
self.m2.register(method)

def unregister(self, method):
self.m1.unregister(method)
self.m2.unregister(method)

class BunchOfPointsDragController(EventsEmitter):
def __init__(self, model):
EventsEmitter.__init__(self)
self.model = model
self.draggedPoint = None

def mouseMovedTo(self, x,y):
if self.draggedPoint != None:
newPoint = (x,y)
draggedPoint = self.draggedPoint
self.draggedPoint = newPoint
self.model.replacePoint(draggedPoint, newPoint)
def buttonDown(self, x,y):
if self.draggedPoint == None:
closePoint = self.getCloseEnoughPoint(x,y)
if closePoint != None:
self.draggedPoint = closePoint
self.emit("dragPointChanged",closePoint)

def buttonUp(self, x,y):
self.mouseMovedTo(x,y)
self.draggedPoint = None
self.emit("dragPointChanged", None)

def getCloseEnoughPoint(self, x,y):
minSquareDistance = 25
closestPoint = None
for point in self.model.points():
dx = X(point) - x
dy = Y(point) - y
distance = dx*dx + dy*dy
if minSquareDistance > distance:
closestPoint = point
minSquareDistance = distance
return closestPoint

def isDraggedPoint(self, p):
return p is self.draggedPoint

class CurvesLinesViewPointsView(object):
def __init__(self, screen, modelCurves, modelLines, model, controller):
self.screen = screen
self.modelLines = modelLines
self.modelCurves = modelCurves
self.controller = controller
controller.register(self.dragPointChanged)
model.register(self.pointsChanged)

def draw(self):
self.screen.fill(Color("black"))
pygame.draw.lines(self.screen, Color("cyan"), 0, self.modelLines.pointsSequence(), 3)
(p0, p1, m0, m1) =  padlib.BezierCurve(screen,modelCurves.pointsSequence(),3,100,Color("magenta"))

self.drawPointSet(self.modelCurves.points(),
lambda(p):self.controller.isDraggedPoint(p),
Color("white"), Color("red"))
self.drawPointSet(self.modelLines.points(),
lambda(p):self.controller.isDraggedPoint(p),
Color("lightgray"), Color("red"))

self.drawSimplePointSet(findIntersectionsManyCurvesManyLines(p0, p1, m0, m1,self.modelLines.points()),
Color("blue"))

def drawSimplePointSet(self, points, normalColor):
self.drawPointSet(points, lambda(p):True, None, normalColor);

def drawPointSet(self, points, specialPoint, normalColor, specialColor):
for p in points:
if specialPoint(p):
draw.circle(self.screen, specialColor, p, 6)
else:
draw.circle(self.screen, normalColor, p, 2)
pygame.display.update()

def dragPointChanged(self, p): self.draw()
def pointsChanged(self, p): self.draw()

class PygameEventsDistributor(EventsEmitter):
def __init__(self):
EventsEmitter.__init__(self)
def processEvent(self, e):
if e.type == MOUSEMOTION:
self.emit("mouseMovedTo", e.pos[0], e.pos[1])
elif e.type == MOUSEBUTTONDOWN:
self.emit("buttonDown", e.pos[0], e.pos[1])
elif e.type == MOUSEBUTTONUP:
self.emit("buttonUp", e.pos[0], e.pos[1])

modelLines = BunchOfPointsModel()
modelCurves = BunchOfPointsModel()
model = BunchOfPointsCompositeModel(modelLines, modelCurves);
controller = BunchOfPointsDragController(model)

distributor = PygameEventsDistributor()
distributor.register(controller.mouseMovedTo)
distributor.register(controller.buttonUp)
distributor.register(controller.buttonDown)

pygame.init()
screen = pygame.display.set_mode((640, 480))

view = CurvesLinesViewPointsView(screen, modelCurves, modelLines, model, controller)

keepGoing = True

try:
while (keepGoing):
for event in pygame.event.get():
if event.type == QUIT:
keepGoing = False
break
distributor.processEvent(event)
pass
finally:
pygame.quit()
``````
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