There are two components to the answer:

- You have to define a transformation that takes a 2-vector to a 2-vector
- If the transformation isn't invertible, then you have to specify the range of indices of the final image manually.

For the first, the following suffices:

```
julia> using StaticArrays, CoordinateTransformations
julia> M = @SMatrix [1 0 0; 0 1 0; -1/1000 0 1] # a 3x3 perspective transformation matrix
3×3 StaticArrays.SArray{Tuple{3,3},Float64,2,9}:
1.0 0.0 0.0
0.0 1.0 0.0
-0.001 0.0 1.0
julia> tform = PerspectiveMap() ∘ inv(LinearMap(M))
(CoordinateTransformations.PerspectiveMap() ∘ LinearMap([1.0 0.0 0.0; -0.0 1.0 0.0; 0.001 -0.0 1.0]))
julia> tform(@SVector([1,1,1])) # this takes a 3-vector as input and returns a 2-vector
2-element SVector{2,Float64}:
0.999001
0.999001
julia> push1(x) = push(x, 1)
push1 (generic function with 1 method)
julia> tform2 = PerspectiveMap() ∘ inv(LinearMap(M)) ∘ push1 # here's one that takes a 2-vector as input (appends 1 to the 2-vector)
(::#55) (generic function with 1 method)
julia> tform2(@SVector([1,1]))
2-element SVector{2,Float64}:
0.999001
0.999001
```

Now let's try this on an image. We'll create an output image that has the same indices as the input image, although you can choose any indices you want:

```
julia> using Images, TestImages
julia> img = testimage("lighthouse");
julia> imgw = warp(img, tform2, indices(img)); # 3rd argument sets the indices
julia> using ImageView
julia> imshow(imgw)
```

`img`

looks like this:

and `imgw`

looks like this: