You are aware that by visually inspecting the point cloud you can already distinguish a multitude of rectangles? In other words, you will likely find many rectangles if you don't do a sort of pre-selection routine...

Anyway, aside from the method already given by @mathematician1975, you can also just check if the sides are (more or less) parallel.

Let's call @mathematician1975's method `method 1`

and parallel-check `method 2`

.
Then:

```
%# method 1:
n1 = |u1-u2| %# 3 sub., 3 mult, 2 add. per distance
n2 = |u3-u2| %# total of 6 distances to compute.
n3 = |u4-u3| %# then max 5+4+3+2+1 = 15 comp. to find unique distances
n4 = |u1-u4|
n5 = |u4-u2| %# Total:
n6 = |u3-u1| %# 12 sub., 18 mult., 12 add, 15 comp
%# method 2:
w1 = u1-u2 %# 3 subtractions per vector
w2 = u3-u2 %# total of 4 vectors to compute
w3 = u3-u2
w4 = u1-u4
%# 12 sub.
abs(w1-w3) == [0 0 0] %# 3 sub., 3 comp., 1 sign.
abs(w2-w4) == [0 0 0] %# 3 sub., 3 comp., 1 sign.
%# Total: 18 sub., 6 comp. 2 sign.
```

Note that these are both worst-case; with a bit of bookkeeping you can drastically reduce the cost of both.

Note also that `method 2`

needs to know beforehand that the vertices are already in the right order. If this is not the case, it'll increase the cost by a factor of 4, which is more that `method 1.`

.

May I ask how you are computing the distances?