Here is a short code snippet which works whenever the cross product makes sense: the 3D version returns a vector and the 2D version returns a scalar. If you just want simple code that gives the right answer without pulling in an external library, this is all you need.

```
# Compute the vector cross product between x and y, and return the components
# indexed by i.
CrossProduct3D <- function(x, y, i=1:3) {
# Project inputs into 3D, since the cross product only makes sense in 3D.
To3D <- function(x) head(c(x, rep(0, 3)), 3)
x <- To3D(x)
y <- To3D(y)
# Indices should be treated cyclically (i.e., index 4 is "really" index 1, and
# so on). Index3D() lets us do that using R's convention of 1-based (rather
# than 0-based) arrays.
Index3D <- function(i) (i - 1) %% 3 + 1
# The i'th component of the cross product is:
# (x[i + 1] * y[i + 2]) - (x[i + 2] * y[i + 1])
# as long as we treat the indices cyclically.
return (x[Index3D(i + 1)] * y[Index3D(i + 2)] -
x[Index3D(i + 2)] * y[Index3D(i + 1)])
}
CrossProduct2D <- function(x, y) CrossProduct3D(x, y, i=3)
```

## Does it work?

Let's check a random example I found online:

```
> CrossProduct3D(c(3, -3, 1), c(4, 9, 2)) == c(-15, -2, 39)
[1] TRUE TRUE TRUE
```

Looks pretty good!

## Why is this better than previous answers?

- It's 3D (Carl's was 2D-only).
- It's simple and idiomatic.
- Nicely commented and formatted; hence, easy to understand

The downside is that the number '3' is hardcoded several times. Actually, this isn't such a bad thing, since it highlights the fact that the vector cross product is *purely* a 3D construct. Personally, I'd recommend ditching cross products entirely and learning Geometric Algebra instead. :)

`crossprod`

documentation-`Vectors are promoted to single-column or single-row matrices, depending on the context.`

.`vectorxprod(A, B)`

would you be willing to share (I guess as an answer)? Thx.2more comments