4

This is an extension of the question posed here (quoted below)

I have a matrix (2d numpy ndarray, to be precise):

A = np.array([[4, 0, 0],
              [1, 2, 3],
              [0, 0, 5]])

And I want to roll each row of A independently, according to roll values in another array:

r = np.array([2, 0, -1])

That is, I want to do this:

print np.array([np.roll(row, x) for row,x in zip(A, r)])

[[0 0 4]
 [1 2 3]
 [0 5 0]]

Is there a way to do this efficiently? Perhaps using fancy indexing tricks?

The accepted solution was:

rows, column_indices = np.ogrid[:A.shape[0], :A.shape[1]]

# Use always a negative shift, so that column_indices are valid.
# (could also use module operation)
r[r < 0] += A.shape[1]
column_indices = column_indices - r[:,np.newaxis]

result = A[rows, column_indices]

I would basically like to do the same thing, except when an index gets rolled "past" the end of the row, I would like the other side of the row to be padded with a NaN, rather than the value move to the "front" of the row in a periodic fashion.

Maybe using np.pad somehow? But I can't figure out how to get that to pad different rows by different amounts.

4
  • It might be more efficient to do this in two steps so you don't need to pad: first roll the rows as in the previous question, then set the r leftmost (and -r rightmost) values of each row to NaN. – abarnert Jul 5 '18 at 22:06
  • @abarnert Would this be using the values in 'r' before doing the negative check? (r[r < 0] += A.shape[1]) EDIT: Also tricky how to figure out how to do this without looping through r – hm8 Jul 5 '18 at 22:18
  • I would create a nan filled array, and then use indexing like this to copy rolled values to it. But your I want to do matrix doesn't show this nan fill! – hpaulj Jul 5 '18 at 22:30
  • This would be after the entire roll operation you show above. First roll, then… basically what @hpaulj said to overwrite the values that rolled around with nans. And actually, the only way I can think of doing the second step (without looping) is to do it twice, one using just the positive elements of r to copy from the nan array to the left side, then using just the negative elements to copy to the right side, but I don't think that'll be an efficiency issue. But it is getting pretty far from simple and elegant, and hopefully one of the numpy wizards will come along with an obvious one-liner… – abarnert Jul 5 '18 at 22:40
7

Inspired by Roll rows of a matrix independently's solution, here's a vectorized one based on np.lib.stride_tricks.as_strided -

from skimage.util.shape import view_as_windows as viewW

def strided_indexing_roll(a, r):
    # Concatenate with sliced to cover all rolls
    p = np.full((a.shape[0],a.shape[1]-1),np.nan)
    a_ext = np.concatenate((p,a,p),axis=1)

    # Get sliding windows; use advanced-indexing to select appropriate ones
    n = a.shape[1]
    return viewW(a_ext,(1,n))[np.arange(len(r)), -r + (n-1),0]

Sample run -

In [76]: a
Out[76]: 
array([[4, 0, 0],
       [1, 2, 3],
       [0, 0, 5]])

In [77]: r
Out[77]: array([ 2,  0, -1])

In [78]: strided_indexing_roll(a, r)
Out[78]: 
array([[nan, nan,  4.],
       [ 1.,  2.,  3.],
       [ 0.,  5., nan]])
0

I was able to hack this together with linear indexing...it gets the right result but performs rather slowly on large arrays.

A = np.array([[4, 0, 0],
              [1, 2, 3],
              [0, 0, 5]]).astype(float)

r = np.array([2, 0, -1])

rows, column_indices = np.ogrid[:A.shape[0], :A.shape[1]]

# Use always a negative shift, so that column_indices are valid.
# (could also use module operation)
r_old = r.copy()
r[r < 0] += A.shape[1]
column_indices = column_indices - r[:,np.newaxis]

result = A[rows, column_indices]

# replace with NaNs
row_length = result.shape[-1]

pad_inds = []
for ind,i in np.enumerate(r_old):
    if i > 0:
        inds2pad = [np.ravel_multi_index((ind,) + (j,),result.shape) for j in range(i)]
        pad_inds.extend(inds2pad)
    if i < 0:
        inds2pad = [np.ravel_multi_index((ind,) + (j,),result.shape) for j in range(row_length+i,row_length)]
        pad_inds.extend(inds2pad)
result.ravel()[pad_inds] = nan

Gives the expected result:

print result

[[ nan  nan   4.]
 [  1.   2.   3.]
 [  0.   5.  nan]]
0

Based on @Seberg and @yann-dubois answers in the non-nan case, I've written a method that:

  • Is faster than the current answer
  • Works on ndarrays of any shape (specify the row-axis using the axis argument)
  • Allows for setting fill to either np.nan, any other "fill value" or False to allow regular rolling across the array edge.

Benchmarking

cols, rows = 1024, 2048
arr = np.stack(rows*(np.arange(cols,dtype=float),))
shifts = np.random.randint(-cols, cols, rows)

np.testing.assert_array_almost_equal(row_roll(arr, shifts), strided_indexing_roll(arr, shifts))
# True

%timeit row_roll(arr, shifts)
# 25.9 ms ± 161 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)

%timeit strided_indexing_roll(arr, shifts)
# 29.7 ms ± 446 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
def row_roll(arr, shifts, axis=1, fill=np.nan):
    """Apply an independent roll for each dimensions of a single axis.

    Parameters
    ----------
    arr : np.ndarray
        Array of any shape.

    shifts : np.ndarray, dtype int. Shape: `(arr.shape[:axis],)`.
        Amount to roll each row by. Positive shifts row right.

    axis : int
        Axis along which elements are shifted. 
        
    fill: bool or float
        If True, value to be filled at missing values. Otherwise just rolls across edges.
    """
    if np.issubdtype(arr.dtype, int) and isinstance(fill, float):
        arr = arr.astype(float)

    shifts2 = shifts.copy()
    arr = np.swapaxes(arr,axis,-1)
    all_idcs = np.ogrid[[slice(0,n) for n in arr.shape]]
    # Convert to a positive shift
    shifts2[shifts2 < 0] += arr.shape[-1] 
    all_idcs[-1] = all_idcs[-1] - shifts2[:, np.newaxis]

    result = arr[tuple(all_idcs)]

    if fill is not False:
        # Create mask of row positions above negative shifts
        # or below positive shifts. Then set them to np.nan.
        *_, nrows, ncols  = arr.shape

        mask_neg = shifts < 0
        mask_pos = shifts >= 0
        
        shifts_pos = shifts.copy()
        shifts_pos[mask_neg] = 0
        shifts_neg = shifts.copy()
        shifts_neg[mask_pos] = ncols+1 # need to be bigger than the biggest positive shift
        shifts_neg[mask_neg] = shifts[mask_neg] % ncols

        indices = np.stack(nrows*(np.arange(ncols),))
        nanmask = (indices < shifts_pos[:, None]) | (indices >= shifts_neg[:, None])
        result[nanmask] = fill

    arr = np.swapaxes(result,-1,axis)

    return arr
1
  • does it work for multiple dims? eg 3? i'm getting unexpected behavior – elbOlita Mar 14 at 23:26

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.