Mapping a NumPy array in place

Is it possible to map a NumPy array in place? If yes, how?

Given `a_values` - 2D array - this is the bit of code that does the trick for me at the moment:

``````for row in range(len(a_values)):
for col in range(len(a_values[0])):
a_values[row][col] = dim(a_values[row][col])
``````

But it's so ugly that I suspect that somewhere within NumPy there must be a function that does the same with something looking like:

``````a_values.map_in_place(dim)
``````

but if something like the above exists, I've been unable to find it.

-
you could do `a_values = np.vectorize(dim)(a_values)` and avoid the nested loops but that's still not in place, so it's not the answer. – Dan D. Jul 26 '11 at 1:02
I don't know of a function that will do this, but if there is one, it only makes the code look neater. If you want the performance speedup that is characteristic of Numpy, then you need to re-write the dim() function to work on numpy arrays directly. – Bob Jul 26 '11 at 1:07
@eryksun yes it would but that's still not in place operation and so its not much better and might incur an additional copy over what i stated – Dan D. Jul 26 '11 at 1:58
I made what I believe was a gallant attempt at abusing `vectorize` but I'm giving up now. Seconding Bob. – senderle Jul 26 '11 at 2:33
@senderle - For whatever it's worth, your gallant attempt seems to work perfectly for me... (And is pretty slick, all things considered) Out of vague curiosity, where was it going wrong? – Joe Kington Jul 26 '11 at 5:07

It's only worth trying to do this in-place if you are under significant space constraints. If that's the case, it is possible to speed up your code a little bit by iterating over a flattened view of the array. Since `reshape` returns a new view when possible, the data itself isn't copied (unless the original has unusual structure).

I don't know of a better way to achieve bona fide in-place application of an arbitrary Python function.

``````>>> def flat_for(a, f):
...     a = a.reshape(-1)
...     for i, v in enumerate(a):
...         a[i] = f(v)
...
>>> a = numpy.arange(25).reshape(5, 5)
>>> flat_for(a, lambda x: x + 5)
>>> a

array([[ 5,  6,  7,  8,  9],
[10, 11, 12, 13, 14],
[15, 16, 17, 18, 19],
[20, 21, 22, 23, 24],
[25, 26, 27, 28, 29]])
``````

Some timings:

``````>>> a = numpy.arange(2500).reshape(50, 50)
>>> f = lambda x: x + 5
>>> %timeit flat_for(a, f)
1000 loops, best of 3: 1.86 ms per loop
``````

It's about twice as fast as the nested loop version:

``````>>> a = numpy.arange(2500).reshape(50, 50)
>>> def nested_for(a, f):
...     for i in range(len(a)):
...         for j in range(len(a[0])):
...             a[i][j] = f(a[i][j])
...
>>> %timeit nested_for(a, f)
100 loops, best of 3: 3.79 ms per loop
``````

Of course vectorize is still faster, so if you can make a copy, use that:

``````>>> a = numpy.arange(2500).reshape(50, 50)
>>> g = numpy.vectorize(lambda x: x + 5)
>>> %timeit g(a)
1000 loops, best of 3: 584 us per loop
``````

And if you can rewrite `dim` using built-in ufuncs, then please, please, don't `vectorize`:

``````>>> a = numpy.arange(2500).reshape(50, 50)
>>> %timeit a + 5
100000 loops, best of 3: 4.66 us per loop
``````

`numpy` does operations like `+=` in place, just as you might expect -- so you can get the speed of a ufunc with in-place application at no cost. Sometimes it's even faster! See here for an example.

By the way, my original answer to this question, which can be viewed in its edit history, is ridiculous, and involved vectorizing over indices into `a`. Not only did it have to do some funky stuff to bypass `vectorize`'s type-detection mechanism, it turned out to be just as slow as the nested loop version. So much for cleverness!

-
Thank you for this (+1) - I will test it when I start working later today. As for why I need this.... arrays are used internally by `pygame.surfarray.pixels2d`. The array is a reference to the image pixel values, not a copy of it, so I need to change the array I got from pygame if I want my image/sprite to be modify in the scene. That said, this is my very first time with pynum, so if I missed something, you are welcome to rectify my understanding! :) – mac Jul 26 '11 at 7:44
@mac, if that's the case, then I would recommend eryksun's solution, as posted in the comments: `a_values[:] = np.vectorize(dim)(a_values)`. It creates a copy, but slice assignment (`a_values[:]`) alters the array in-place. Let me know if that doesn't work. – senderle Jul 26 '11 at 13:57
@mac, also, if you plan to reuse the vectorized version of `dim`, it's probably wise to give it its own name, so that you aren't calling `vectorize` all the time. – senderle Jul 26 '11 at 14:02
@mac, and finally, if you can rewrite dim using ufuncs, then slice assignment + ufunc_dim (`a_values[:] = ufunc_dim(a_values)`) will be the best solution, hands down. – senderle Jul 26 '11 at 14:04
@eryksun, based on mac's new comments, your solution is the best one. An answer from you would have my upvote. – senderle Jul 26 '11 at 14:06

This is a write-up of contributions scattered in answers and comments, that I wrote after accepting the answer to the question. Upvotes are always welcome, but if you upvote this answer, please don't miss to upvote also those of senderle and (if (s)he writes one) eryksun, who suggested the methods below.

Q: Is it possible to map a numpy array in place?
A: Yes but not with a single array method. You have to write your own code.

Below a script that compares the various implementations discussed in the thread:

``````import timeit
from numpy import array, arange, vectorize, rint

# SETUP
get_array = lambda side : arange(side**2).reshape(side, side) * 30
dim = lambda x : int(round(x * 0.67328))

# TIMER
def best(fname, reps, side):
global a
a = get_array(side)
t = timeit.Timer('%s(a)' % fname,
setup='from __main__ import %s, a' % fname)
return min(t.repeat(reps, 3))  #low num as in place --> converge to 1

# FUNCTIONS
def mac(array_):
for row in range(len(array_)):
for col in range(len(array_[0])):
array_[row][col] = dim(array_[row][col])

def mac_two(array_):
li = range(len(array_[0]))
for row in range(len(array_)):
for col in li:
array_[row][col] = int(round(array_[row][col] * 0.67328))

def mac_three(array_):
for i, row in enumerate(array_):
array_[i][:] = [int(round(v * 0.67328)) for v in row]

def senderle(array_):
array_ = array_.reshape(-1)
for i, v in enumerate(array_):
array_[i] = dim(v)

def eryksun(array_):
array_[:] = vectorize(dim)(array_)

def ufunc_ed(array_):
multiplied = array_ * 0.67328
array_[:] = rint(multiplied)

# MAIN
r = []
for fname in ('mac', 'mac_two', 'mac_three', 'senderle', 'eryksun', 'ufunc_ed'):
print('\nTesting `%s`...' % fname)
r.append(best(fname, reps=50, side=50))
# The following is for visually checking the functions returns same results
tmp = get_array(3)
eval('%s(tmp)' % fname)
print tmp
tmp = min(r)/100
print('\n===== ...AND THE WINNER IS... =========================')
print('  mac (as in question)       :  %.4fms [%.0f%%]') % (r[0]*1000,r[0]/tmp)
print('  mac (optimised)            :  %.4fms [%.0f%%]') % (r[1]*1000,r[1]/tmp)
print('  mac (slice-assignment)     :  %.4fms [%.0f%%]') % (r[2]*1000,r[2]/tmp)
print('  senderle                   :  %.4fms [%.0f%%]') % (r[3]*1000,r[3]/tmp)
print('  eryksun                    :  %.4fms [%.0f%%]') % (r[4]*1000,r[4]/tmp)
print('  slice-assignment w/ ufunc  :  %.4fms [%.0f%%]') % (r[5]*1000,r[5]/tmp)
print('=======================================================\n')
``````

The output of the above script - at least in my system - is:

``````  mac (as in question)       :  88.7411ms [74591%]
mac (optimised)            :  86.4639ms [72677%]
mac (slice-assignment)     :  79.8671ms [67132%]
senderle                   :  85.4590ms [71832%]
eryksun                    :  13.8662ms [11655%]
slice-assignment w/ ufunc  :  0.1190ms [100%]
``````

As you can observe, using numpy's `ufunc` increases speed of more than 2 and almost 3 orders of magnitude compared with the second best and worst alternatives respectively.

If using `ufunc` is not an option, here's a comparison of the other alternatives only:

``````  mac (as in question)       :  91.5761ms [672%]
mac (optimised)            :  88.9449ms [653%]
mac (slice-assignment)     :  80.1032ms [588%]
senderle                   :  86.3919ms [634%]
eryksun                    :  13.6259ms [100%]
``````

HTH!

-
This is one of the best self-answers I've seen, and deserves an upvote :). – senderle Jul 26 '11 at 17:37
Also, the chunked slice-assignment trick is interesting (in `mac_three`), and I find myself wondering if you could achieve a persuasive compromise between space- and time- efficiency using a ufunc in place of a list comprehension -- by processing, say, 10% of the array per iteration, or something like that. – senderle Jul 26 '11 at 17:54
@senderle - Thank you for both the appreciation and the input for solving the question! ;) In my application I use this function only to generate the about 100 10x10 pixels sprites at initialisation time, so I'm not really in pursuit of hyper-optimisation... My original question was truly just inspired by the wish to make my code neater / learning something new, but I posted the source of the test precisely to allow others to keep on playing with this, if so they wish! :) – mac Jul 26 '11 at 22:50
I know this is old, but three comments. 1. I would make `dim` etc. local in all of the cases to reduce overhead and better show the proportions of the differences between the cases. 2. It's possible Senderle's can be micro-optimized by using `array_set = array_.__setitem__; any(array_set(i, dim(x)) for i, x in enumerate(array_))`. 3. I'm not sure eryksun's version is truly in-place. Has this been traced? In some cases the right hand item in slice assignment is fully evaluated to speed up the actual assignment, so a copy is transiently created. – agf Nov 10 '12 at 16:12
I am trying to use this as an exercise to learn the arcana of Python. However, with Python 3.3 I get the following error: Traceback (most recent call last): File "C:\Users\Adriano\Google Drive\python\test.py", line 56, in <module> print(' mac (as in question) : %.4fms [%.0f%%]') % (r[0]*1000,r[0]/tmp) TypeError: unsupported operand type(s) for %: 'NoneType' and 'tuple' – aag Jul 19 '14 at 19:31

Why not using numpy implementation, and the out_ trick ?

``````from numpy import array, arange, vectorize, rint, multiply, round as np_round

def fmilo(array_):
np_round(multiply(array_ ,0.67328, array_), out=array_)
``````

got:

``````===== ...AND THE WINNER IS... =========================
mac (as in question)       :  80.8470ms [130422%]
mac (optimised)            :  80.2400ms [129443%]
mac (slice-assignment)     :  75.5181ms [121825%]
senderle                   :  78.9380ms [127342%]
eryksun                    :  11.0800ms [17874%]
slice-assignment w/ ufunc  :  0.0899ms [145%]
fmilo                      :  0.0620ms [100%]
=======================================================
``````
-
It looks nice... but it doesn't work! :( The results you are getting out of this function (`[[ 0 20 40][ 60 80 100][121 141 161]]`) are for some reason - inconsistent with the those of the other tested ones (`[[ 0 20 40][ 61 81 101][121 141 162]]`). If you can fix this, I'll be happy to include your solution in my answer + upvote yours! :) – mac Jul 29 '11 at 0:39
@mac, @fabrizioM, I think I see what's happening. When you pass an output array to a numpy ufunc via `out`, it automatically casts the result to the type of the output array. So in this case, the floating point result is cast to an int (and thus truncated) before being stored. So `fmilo` is functionally equivalent to `array_ *= 0.67328`. To get the desired rounding behavior, you have to do something like `rint((array_ * 0.67328), array_)`. But on my machine that's actually slower than slice assignment. – senderle Jul 29 '11 at 16:02

if ufuncs are not possible, you should maybe consider using cython. it is easy to integrate and give big speedups on specific use of numpy arrays.

-
True (+1). If you provide a snippet to achieve this, I'll be glad to integrate it in my answer with testing etc... – mac Jul 27 '11 at 10:05