# Optimizing the rounding of all elements in a 2-dimensional array

I have a 2 dimensional numpy array, and I would like each element to be rounded to the closest number in a sequence. The array has shape `(28000, 24)`.

The sequence, for instance, would be `[0, 0.05, 0.2, 0.33, 0.5]`.

E.g. an original `0.27` would be rounded to `0.33`, and `0.42` would be rounded to `0.5`

This is what I use so far, but it is of course really slow with a double loop.

MWE:

``````arr = np.array([[0.14, 0.18], [0.20, 0.27]])
new = []
sequence = np.array([0, 0.05, 0.2, 0.33, 0.5])
for i in range(len(arr)):
row = []
for j in range(len(arr[0])):
temp = (arr[i][j] - sequence)**2
row.append(list(sequence[np.where(temp == min(temp))])[0])
new.append(row)
``````

Result:

``````[[0.2000001, 0.2000001], [0.2000001, 0.33000001]]
``````

Motivation:

In machine learning, I am making predictions. Since the outcomes are reflections of confidence by experts, it could be that 2/3 gave a 1 (thus 0.66). So, in this data, relatively many 0, 0.1, 0.2, 0.33, 0.66, 0.75 etc. would occur. My predictions are however something like 0.1724. I would remove a lot of prediction error by rounding in this case to 0.2.

How to optimize rounding all elements?

Update: I now pre-allocated memory, so there doesn't have to be constant appending.

`````` # new = [[0]*len(arr[0])] * len(arr), then unloading into new[i][j],
``````

Timings:

``````Original problem: 36.62 seconds
Pre-allocated array: 15.52 seconds
shx2 SOLUTION 1 (extra dimension): 0.47 seconds
shx2 SOLUTION 2 (better for big arrays): 4.39 seconds
Jaime's np.digitize: 0.02 seconds
``````
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Those are your expected result? Can you give more example about how do you want to round? –  Christian Nov 1 '13 at 8:08
@Christian The key here is the np.linspace, it's basically a list of options which could be rounded to. In this case, it contains `[0, 0.1, 0.2, ... 1]`. –  PascalvKooten Nov 1 '13 at 8:09
Updated the question to reflect the real problem. –  PascalvKooten Nov 1 '13 at 8:15

Another truly vectorized solution with intermediate storage not larger than the array to be processed could be built around `np.digitize`.

``````>>> def round_to_sequence(arr, seq):
...     rnd_thresholds = np.add(seq[:-1], seq[1:]) / 2
...     arr = np.asarray(arr)
...     idx = np.digitize(arr.ravel(), rnd_thresholds).reshape(arr.shape)
...     return np.take(seq, idx)
...
>>> round_to_sequence([[0.14, 0.18], [0.20, 0.27]],
...                   [0, 0.05, 0.2, 0.33, 0.5])
array([[ 0.2 ,  0.2 ],
[ 0.2 ,  0.33]])
``````

UPDATE So what's going on... The first line in the function figures out what the mid points between the items in the sequence are. This values are the thresholds for rounding: below it, you have to round down, above it, you have to round up. I use `np.add`, instead of the more clear `seq[:-1] + seq[1:]` so that it accepts a list or tuple without needing to explicitly convert it to a numpy array.

``````>>> seq = [0, 0.05, 0.2, 0.33, 0.5]
>>> rnd_threshold = np.add(seq[:-1], seq[1:]) / 2
>>> rnd_threshold
array([ 0.025,  0.125,  0.265,  0.415])
``````

Next we use `np.digitize` to find out in what bin, as delimited by those threshold values, each item in the array is. `np.digitize` only takes 1D arrays, so we have to do the `.ravel` plus `.reshape` thing to keep the original shape of the array. As is, it uses the standard convention that items on the limit are rounded up, you could reverse this behavior by using the `right` keyword argument.

``````>>> arr = np.array([[0.14, 0.18], [0.20, 0.27]])
>>> idx = np.digitize(arr.ravel(), seq).reshape(arr.shape)
>>> idx
array([[2, 2],
[3, 3]], dtype=int64)
``````

Now all we need to do is create an array the shape of `idx`, using its entries to index the sequence of values to round to. This could be achieved with `seq[idx]`, but it is often (always?) faster (see here) to use `np.take`.

``````>>> np.take(seq, idx)
array([[ 0.2 ,  0.2 ],
[ 0.33,  0.33]])
``````
-
This is really great. If you provide explanation, I will mark this as the answer since it is roughly 20-25 times faster than the currently accepted answer. –  PascalvKooten Nov 1 '13 at 15:57

# Original Question

The original question stated that the OP wanted to round to the nearest `0.1`, which has the following simple solution...

Really simple - let `numpy` do it for you:

``````arr = np.array([[0.14, 0.18], [0.20, 0.27]])
numpy.around(arr, decimals=1)
``````

When developing scientific software in Python, it is key to avoid loops if possible. If `numpy` has a procedure to do something, use it.

-
I only used it as an example, I shouldn't have I realised now. I am not interested in the decimal only case. What if the list would contain `[0, 0,1 0.33, 0.5, 0.2]`? –  PascalvKooten Nov 1 '13 at 8:10
Awesome answer Alex! :) I was going to give a raw python solution, but this is awesome. –  Games Brainiac Nov 1 '13 at 8:10
And profile too, which you may have done... –  Alex Chamberlain Nov 1 '13 at 8:11
@Dualinity I think you can still remove the loops. Will the list ever be "large"? Or does the list have a better definition than just a list of numbers? –  Alex Chamberlain Nov 1 '13 at 8:12
I surely hope so, but how in this case? My apologies for choosing an example that has such a solution, my intention is indeed to round to anything. –  PascalvKooten Nov 1 '13 at 8:14

I would like to suggest two solutions to your problem. The first is a pure numpy solution, but if you original array is NxM, and sequence size is K, it uses an array of size NxMxK. So this solution is good only if this size is not gigantic in your case. It can still turn out to be very fast despite the big array used, for doing all the work in the numpy space.

The second is a hybrid approach (and turns out to be much simpler to code, too), using `@np.vectorize`. It does looping in numpy space, but calls back to python for each element. The upside is that it avoids creating the huge array.

Both are valid solutions. You choose the one which works best with your array sizes.

Also, both work with arrays with any number of dimensions.

SOLUTION 1

``````import numpy as np

a = np.random.random((2,4))
a
=>
array([[ 0.5501662 ,  0.13055979,  0.579619  ,  0.3161156 ],
[ 0.07327783,  0.45156743,  0.38334009,  0.48772392]])

seq = np.array([ 0.1, 0.3, 0.6, 0.63 ])

# create 3-dim array of all the distances
all_dists = np.abs(a[..., np.newaxis] - seq)
all_dists.shape
=> (2, 4, 4)
all_dists
=>
array([[[ 0.4501662 ,  0.2501662 ,  0.0498338 ,  0.0798338 ],
[ 0.03055979,  0.16944021,  0.46944021,  0.49944021],
[ 0.479619  ,  0.279619  ,  0.020381  ,  0.050381  ],
[ 0.2161156 ,  0.0161156 ,  0.2838844 ,  0.3138844 ]],

[[ 0.02672217,  0.22672217,  0.52672217,  0.55672217],
[ 0.35156743,  0.15156743,  0.14843257,  0.17843257],
[ 0.28334009,  0.08334009,  0.21665991,  0.24665991],
[ 0.38772392,  0.18772392,  0.11227608,  0.14227608]]])

# find where each element gets its closest, i.e. min dist
closest_idxs = all_dists.argmin(axis = -1)
closest_idxs
=>
array([[2, 0, 2, 1],
[0, 2, 1, 2]])

# choose
seq[closest_idxs]
=>
array([[ 0.6,  0.1,  0.6,  0.3],
[ 0.1,  0.6,  0.3,  0.6]])
``````

SOLUTION 2

``````@np.vectorize
def find_closest(x):
dists = np.abs(x-seq)
return seq[dists.argmin()]

find_closest(a)
=>
array([[ 0.6,  0.1,  0.6,  0.3],
[ 0.1,  0.6,  0.3,  0.6]])
``````
-
I was just coming up with a similar solution; +1. –  Alex Chamberlain Nov 1 '13 at 8:30
Amazing! I lowered my prediction error by around 0.3%, which is huge, but it is also blazingly fast! I'll add the timings. –  PascalvKooten Nov 1 '13 at 8:37
Please also see my edit –  shx2 Nov 1 '13 at 8:38
Updated. Thank you very much for this effort. –  PascalvKooten Nov 1 '13 at 8:43
@Dualinity my pleasure –  shx2 Nov 1 '13 at 8:45