taking the dot product suggestion a step further, check if two of the vectors made by any 3 of the points of the points are perpendicular and then see if the x and y match the fourth point.

If you have points [Ax,Ay] [Bx,By] [Cx,Cy] [Dx,Dy]

vector v = B-A
vector u = C-A

v(dot)u/|v||u| == cos(theta)

so if (v.u == 0) there's a couple of perpendicular lines right there.

I actually don't know C programming, but here's some "meta" programming for you :P

```
if (v==[0,0] || u==[0,0] || u==v || D==A) {not a rectangle, not even a quadrilateral}
var dot = (v1*u1 + v2*u2); //computes the "top half" of (v.u/|v||u|)
if (dot == 0) { //potentially a rectangle if true
if (Dy==By && Dx==Cx){
is a rectangle
}
else if (Dx==Bx && Dy==Cy){
is a rectangle
}
}
else {not a rectangle}
```

there's no square roots in this, and no potential for a divide by zero. I noticed people mentioning these issues on earlier posts so I thought I'd offer an alternative.

So, computationally, you need four subtractions to get v and u, two multiplications, one addition and you have to check somewhere between 1 and 7 equalities.

maybe I'm making this up, but i vaguely remember reading somewhere that subtractions and multiplications are "faster" calculations. I assume that declaring variables/arrays and setting their values is also quite fast?

Sorry, I'm quite new to this kind of thing, so I'd love some feedback to what I just wrote.

Edit: try this based on my comment below:

```
A = [a1,a2];
B = [b1,b2];
C = [c1,c2];
D = [d1,d2];
u = (b1-a1,b2-a2);
v = (c1-a1,c2-a2);
if ( u==0 || v==0 || A==D || u==v)
{!rectangle} // get the obvious out of the way
var dot = u1*v1 + u2*v2;
var pgram = [a1+u1+v1,a2+u2+v2]
if (dot == 0 && pgram == D) {rectangle} // will be true 50% of the time if rectangle
else if (pgram == D) {
w = [d1-a1,d2-a2];
if (w1*u1 + w2*u2 == 0) {rectangle} //25% chance
else if (w1*v1 + w2*v2 == 0) {rectangle} //25% chance
else {!rectangle}
}
else {!rectangle}
```