The following Python code will repeatedly add the vector
[1, 2, 3, 4] to each row in the two-dimensional array
a, starting only from the 20th row.
import numpy as np # an array of shape (100, 4) a = np.zeros((100, 4), dtype=np.float32) # and this is the operation explained above a[20:, :] += [1.0, 2.0, 3.0, 0.0]
Is there a simple equivalent of this with
I can already do what I need with more complicated messy looking code but feel there is probably a tidy ndarray.rs equivalent.
OK so, at the risk of over complicating a question I thought might have a simple answer that I just couldn't unearth...
I am using arrays of f32 shape (n, 8) representing three vertex locations, three normal components and two texture mapping coordinates. I am merging buffers from multiple 3D objects into one for more efficient graphics rendering. Within the 8 wide array the first three values need to be scaled i.e. multiplied by
&[sx, sy, sz] then rotated using a standard
rz.dot(&rx.dot(&ry.dot())) function and finally have a displacement
&[dx, dy, dz] added. The normals just need to be rotated. My current system involves holding data in intermediate array variables.
use ndarray as nd; array_buffer: nd::Array2<f32>, loc: &[f32; 3], scl: &[f32; 3]... ... // scale then rotate new verts then add displacement let new_verts = &new_buf.array_buffer.slice(s![.., 0..3]) * &nd::arr1(scl); let new_verts = rotate_vec(rot, &new_verts) + &nd::arr1(loc); // then add them to existing verts let mut verts = nd::stack(nd::Axis(0), &[old_buf.array_buffer.slice(s![.., 0..3]), new_verts.view()]).unwrap(); ...
I know I won't be able to reduce it to the numpy one liner
verts = np.append(old_buf.array_buffer[:,0:3], rotate_vec(rot, (new_buf.array_buffer[:,0:3] * scl) + loc))
but I thought that maybe some of the map or zip variants or macros might help me.