I need to change a triangle by replacing one of its points. However, I need to detect if doing so would cause the triangle to flip.

For example, the triangle defined by the points:

```
[(1.0,1.0), (2.0,3.0), (3.0,1.0)]
```

would look like this:

If I change the third point from `(3.0,1.0)`

to `(1.0,2.0)`

, it flips, as shown here:

I've written a function that detects if a triangle is flipped by calculating the equation for the stationary points and detecting a sign difference in the y-intercept:

```
def would_flip(stationary, orig_third_point, candidate_third_point):
#m = (y2-y1)/(x2-x1)
slope = (stationary[1][3] - stationary[0][4]) / (stationary[1][0] - stationary[0][0])
#y = mx + b
#b = y-mx
yint = stationary[0][5] - slope * stationary[0][0]
orig_atline = slope * orig_third_point[0] + yint
candidate_atline = slope * candidate_third_point[0] + yint
if orig_atline > orig_third_point[1] and not(candidate_atline > candidate_third_point[1]) or \
orig_atline < orig_third_point[1] and not(candidate_atline < candidate_third_point[1]):
return True
return False
```

This works nicely for most cases:

```
>>> would_flip([(1.0,1.0), (2.0,3.0)], (3.0,1.0), (1.0,2.0))
True
>>> would_flip([(1.0,1.0), (2.0,3.0)], (3.0,1.0), (4.0,2.0))
False
```

The problem I have is that if the stationary points are vertical, the slope is infinite:

```
>>> would_flip([(1.0,1.0), (1.0,3.0)], (3.0,1.0), (4.0,2.0))
ZeroDivisionError: float division by zero
```

Is there a better/faster way to detect a triangle flip that is robust to the stationary points being a vertical line? The fact that it's written in python is not important. I will accept an answer that is just a formula or well-described technique.

**EDIT: More information on what it means for a triangle to "flip"**

Consider the four triangles below:

The top-left is the original triangle. The red line (same in all four) are the two stationary points. The rest of the three triangles replace the third point. The top-right and bottom-left triangles are not flipped, while the triangle in the bottom-right is flipped. Essentially, the triangle is "flipped" if the third point ends up on the opposite side of the imaginary line formed by the two stationary points.

**UPDATE2: Working function using cross product:**

```
def would_flip2(stationary, orig_third_point, candidate_third_point):
vec1 = numpy.array([stationary[1][0] - stationary[0][0], stationary[1][1] - stationary[0][1], 0])
vec2_orig = numpy.array([orig_third_point[0] - stationary[0][0], orig_third_point[1] - stationary[0][1], 0])
vec2_candidate = numpy.array([candidate_third_point[0] - stationary[0][0], candidate_third_point[1] - stationary[0][1], 0])
orig_direction = numpy.cross(vec1, vec2_orig)[2]
candidate_direction = numpy.cross(vec1, vec2_candidate)[2]
if orig_direction > 0 and not(candidate_direction > 0) or \
orig_direction < 0 and not(candidate_direction < 0):
return True
return False
```