How can I tell whether two triangles intersect in 2D Euclidean space? (i.e. classic 2D geometry) given the (X,Y) coordinates of each vertex in each triangle.

Re the truly most efficient algorithm, there has not been much work done on that question  nobody has decisively shown which variation is fastest. One problem is that a lot of the discussion involves tris in 3D space. Eg realtimecollisiondetection.net/blog/?p=29 PS Such problems are often cast in terms of points being on the "correct side" of a line segment. Eg mochima.com/articles/cuj_geometry_article/… As Nick points out in his last para, in practice it is all about how good you do culling. – Fattie Dec 27 '11 at 12:15
One way is to check if two sides of triangle A intersect with any side of triangle B, and then check all six possibilities of a point of A inside B or a point of B inside A.
For a point inside a triangle see for example: Point in triangle test.
When we test collisions on polygons we also have a surrounding rectangle for our polygons. So we first test for rectangle collisions and if there is a hit we proceed with polygon collision detection.

hi @Joe. It's correct that we should check all 3 sides of A against all 3 sides of B. But since we're going to check if A's corners are inside B (and vice versa)  after the line segment intersection checks  the whole procedure still works. That's because if we detect any corner inside the other triangle, we have a collision. – Nick Dandoulakis Dec 27 '11 at 10:36


1Only need 4 point in triangle tests. jsfiddle.net/eyal/gxw3632c This is not a fast algorithm for triangletriangle intersection – Eyal May 30 '17 at 20:08
Python implementation for line intersection and point in triangle test, with a little modification.
def line_intersect2(v1,v2,v3,v4):
'''
judge if line (v1,v2) intersects with line(v3,v4)
'''
d = (v4[1]v3[1])*(v2[0]v1[0])(v4[0]v3[0])*(v2[1]v1[1])
u = (v4[0]v3[0])*(v1[1]v3[1])(v4[1]v3[1])*(v1[0]v3[0])
v = (v2[0]v1[0])*(v1[1]v3[1])(v2[1]v1[1])*(v1[0]v3[0])
if d<0:
u,v,d= u,v,d
return (0<=u<=d) and (0<=v<=d)
def point_in_triangle2(A,B,C,P):
v0 = [C[0]A[0], C[1]A[1]]
v1 = [B[0]A[0], B[1]A[1]]
v2 = [P[0]A[0], P[1]A[1]]
cross = lambda u,v: u[0]*v[1]u[1]*v[0]
u = cross(v2,v0)
v = cross(v1,v2)
d = cross(v1,v0)
if d<0:
u,v,d = u,v,d
return u>=0 and v>=0 and (u+v) <= d
def tri_intersect2(t1, t2):
'''
judge if two triangles in a plane intersect
'''
if line_intersect2(t1[0],t1[1],t2[0],t2[1]): return True
if line_intersect2(t1[0],t1[1],t2[0],t2[2]): return True
if line_intersect2(t1[0],t1[1],t2[1],t2[2]): return True
if line_intersect2(t1[0],t1[2],t2[0],t2[1]): return True
if line_intersect2(t1[0],t1[2],t2[0],t2[2]): return True
if line_intersect2(t1[0],t1[2],t2[1],t2[2]): return True
if line_intersect2(t1[1],t1[2],t2[0],t2[1]): return True
if line_intersect2(t1[1],t1[2],t2[0],t2[2]): return True
if line_intersect2(t1[1],t1[2],t2[1],t2[2]): return True
inTri = True
inTri = inTri and point_in_triangle2(t1[0],t1[1],t1[2], t2[0])
inTri = inTri and point_in_triangle2(t1[0],t1[1],t1[2], t2[1])
inTri = inTri and point_in_triangle2(t1[0],t1[1],t1[2], t2[2])
if inTri == True: return True
inTri = True
inTri = inTri and point_in_triangle2(t2[0],t2[1],t2[2], t1[0])
inTri = inTri and point_in_triangle2(t2[0],t2[1],t2[2], t1[1])
inTri = inTri and point_in_triangle2(t2[0],t2[1],t2[2], t1[2])
if inTri == True: return True
return False
There is a full interactive demo.

This gets the wrong answer in this case:
t1 = [[0,0],[5,0],[0,5]]; t2 = [[10,0],[5,0],[1,6]]; print (tri_intersect2(t1, t2), False)
– TimSC Mar 27 '16 at 17:30 
1@TimSC Yes, it fails to detect intersection for two parallel lines. You can enforce that d is greater than a little positve number in function
line_intersect2
. – Martin Wang Mar 28 '16 at 15:05 
1You don't need to do all 9 line intersections, you can do just 8. Because if one of the triangles crosses over into the other, it must also cross back out. So if there is 1 intersection, there must be two. Also, you don't need all the point in triangle tests because, if there are no intersections, then either all the points are inside or none. So you can do 8 line_intersect and 2 point in Triangle. Or do 6 line_intersect and then 6 point in Triangle. Depends what's faster for you. – Eyal May 7 '17 at 11:57
Here is my attempt at the triangletriangle collision problem (implemented in python):
#2D TriangleTriangle collisions in python
#Release by Tim SheermanChase 2016 under CC0
import numpy as np
def CheckTriWinding(tri, allowReversed):
trisq = np.ones((3,3))
trisq[:,0:2] = np.array(tri)
detTri = np.linalg.det(trisq)
if detTri < 0.0:
if allowReversed:
a = trisq[2,:].copy()
trisq[2,:] = trisq[1,:]
trisq[1,:] = a
else: raise ValueError("triangle has wrong winding direction")
return trisq
def TriTri2D(t1, t2, eps = 0.0, allowReversed = False, onBoundary = True):
#Trangles must be expressed anticlockwise
t1s = CheckTriWinding(t1, allowReversed)
t2s = CheckTriWinding(t2, allowReversed)
if onBoundary:
#Points on the boundary are considered as colliding
chkEdge = lambda x: np.linalg.det(x) < eps
else:
#Points on the boundary are not considered as colliding
chkEdge = lambda x: np.linalg.det(x) <= eps
#For edge E of trangle 1,
for i in range(3):
edge = np.roll(t1s, i, axis=0)[:2,:]
#Check all points of trangle 2 lay on the external side of the edge E. If
#they do, the triangles do not collide.
if (chkEdge(np.vstack((edge, t2s[0]))) and
chkEdge(np.vstack((edge, t2s[1]))) and
chkEdge(np.vstack((edge, t2s[2])))):
return False
#For edge E of trangle 2,
for i in range(3):
edge = np.roll(t2s, i, axis=0)[:2,:]
#Check all points of trangle 1 lay on the external side of the edge E. If
#they do, the triangles do not collide.
if (chkEdge(np.vstack((edge, t1s[0]))) and
chkEdge(np.vstack((edge, t1s[1]))) and
chkEdge(np.vstack((edge, t1s[2])))):
return False
#The triangles collide
return True
if __name__=="__main__":
t1 = [[0,0],[5,0],[0,5]]
t2 = [[0,0],[5,0],[0,6]]
print (TriTri2D(t1, t2), True)
t1 = [[0,0],[0,5],[5,0]]
t2 = [[0,0],[0,6],[5,0]]
print (TriTri2D(t1, t2, allowReversed = True), True)
t1 = [[0,0],[5,0],[0,5]]
t2 = [[10,0],[5,0],[1,6]]
print (TriTri2D(t1, t2), False)
t1 = [[0,0],[5,0],[2.5,5]]
t2 = [[0,4],[2.5,1],[5,4]]
print (TriTri2D(t1, t2), True)
t1 = [[0,0],[1,1],[0,2]]
t2 = [[2,1],[3,0],[3,2]]
print (TriTri2D(t1, t2), False)
t1 = [[0,0],[1,1],[0,2]]
t2 = [[2,1],[3,2],[3,4]]
print (TriTri2D(t1, t2), False)
#Barely touching
t1 = [[0,0],[1,0],[0,1]]
t2 = [[1,0],[2,0],[1,1]]
print (TriTri2D(t1, t2, onBoundary = True), True)
#Barely touching
t1 = [[0,0],[1,0],[0,1]]
t2 = [[1,0],[2,0],[1,1]]
print (TriTri2D(t1, t2, onBoundary = False), False)
It works based based on the fact that the triangles do not overlap if all the points of triangle 1 are on the external side of at least one of the edges of triangle 2 (or vice versa is true). Of course, triangles are never concave.
I don't know if this approach is more or less efficient than the others.
Bonus: I ported it to C++ https://gist.github.com/TimSC/5ba18ae21c4459275f90
As stated, you'll need to check that a point is inside a triangle. The simplest way to check if a point is inside a closed polygon is to draw a straight line in any direction from the point and count how many times the line crosses a vertex. If the answer is odd then the point is in the polygon, even, then it's outside.
The simplest straight line to check is the one going horizontally to the right of the point (or some other perpendicular direction). This makes the check for vertex crossing nearly trivial. The following checks should suffice:
Is the point's ycoordinate between the ycoordinates of the two end points of the vertex? No, then doesn't cross.
Is the point's xcoordinate greater than the furthest right end point of the vertex? Yes, then doesn't cross.
Is the point's xcoordinate less than the furthest left end point of the vertex? Yes, then does cross.
If the cases above fail, then you can use the cross product of the vector representing the vertex and a vector formed from the end of the vertex to the point. A negative answer will indicate the point lies on one side of the vertex, a positive answer on the other side of the vertex, and a zero answer on the vertex. This works because a cross product involves taking the sine of two vectors.

This won't tell you if two triangles intersect, which was the question. You can't just test one triangle's vertices, as triangles can intersect without any vertices being inside each other (e.g. star of david). – Ergwun May 6 '15 at 8:46

Do you really think it will helps with "What's the most efficient way to detect triangletriangle intersections?" – tvorez Jan 24 at 12:17
What you're really looking for is a "Point in Polygon" algorithm. If any of the points of one triangle are in the other, they are intersecting. Here is a good question to check out.

17This won't give a general solution, since it's possible for two triangles to overlap without either of their vertices being inside the other. – gnovice Oct 18 '09 at 18:01

if only a tiny point overlap, it is hard to know which point to select for test – Jerry Zhang Nov 21 '17 at 0:31