Here's a custom function that allows stepping through decimal increments:

def my_range(start, stop, step):
    i = start
    while i < stop:
        yield i
        i += step

It works like this:

out = list(my_range(0, 1, 0.1))

[0, 0.1, 0.2, 0.30000000000000004, 0.4, 0.5, 0.6, 0.7, 0.7999999999999999, 0.8999999999999999, 0.9999999999999999]

Now, there's nothing surprising about this. It's understandable this happens because of floating point inaccuracies and that 0.1 has no exact representation in memory. So, those precision errors are understandable.

Take numpy on the other hand:

import numpy as np

out = np.arange(0, 1, 0.1)
array([ 0. ,  0.1,  0.2,  0.3,  0.4,  0.5,  0.6,  0.7,  0.8,  0.9]) 

What's interesting is that there are no visible imprecision accuracies introduced here. I thought this might have to do with what the __repr__ shows, so to confirm, I tried this:

x = list(my_range(0, 1.1, 0.1))[-1]


x = list(np.arange(0, 1.1, 0.1))[-1]


So, my function returns an incorrect upper value (it should be 1.0 but it is actually 1.0999999999999999), but np.arange does it correctly.

I'm aware of Is floating point math broken? but the point of this question is:

How does numpy do this?

  • 1
    At a guess, if numpy uses floating point multiplication, this can be a little less error prone. 0.1 * 10 == 1.0, but 0.1 + 0.1 + ... != 1.0. – Izaak van Dongen Aug 27 '17 at 16:45
  • Also try with numpy.set_printoptions(precision=18). – user707650 Aug 27 '17 at 16:48
  • I know I probably shouldn't post such a comment but: Thanks for asking the question. Because of that question I investigated the very interesting topic of floating point error accumulation (again), I made a pull request to fix a code-comment regarding an np.arange helper function and ... I got my NumPy gold badge because of the upvotes here! So thank you!!! – MSeifert Aug 27 '17 at 18:32
  • @MSeifert Congrats to you and thanks for answering :) – coldspeed Aug 27 '17 at 19:15
up vote 10 down vote accepted

The difference in endpoints is because NumPy calculates the length up front instead of ad hoc, because it needs to preallocate the array. You can see this in the _calc_length helper. Instead of stopping when it hits the end argument, it stops when it hits the predetermined length.

Calculating the length up front doesn't save you from the problems of a non-integer step, and you'll frequently get the "wrong" endpoint anyway, for example, with numpy.arange(0.0, 2.1, 0.3):

In [46]: numpy.arange(0.0, 2.1, 0.3)
Out[46]: array([ 0. ,  0.3,  0.6,  0.9,  1.2,  1.5,  1.8,  2.1])

It's much safer to use numpy.linspace, where instead of the step size, you say how many elements you want and whether you want to include the right endpoint.

It might look like NumPy has suffered no rounding error when calculating the elements, but that's just due to different display logic. NumPy is truncating the displayed precision more aggressively than float.__repr__ does. If you use tolist to get an ordinary list of ordinary Python scalars (and thus the ordinary float display logic), you can see that NumPy has also suffered rounding error:

In [47]: numpy.arange(0, 1, 0.1).tolist()

It's suffered slightly different rounding error - for example, in .6 and .7 instead of .8 and .9 - because it also uses a different means of computing the elements, implemented in the fill function for the relevant dtype.

The fill function implementation has the advantage that it uses start + i*step instead of repeatedly adding the step, which avoids accumulating error on each addition. However, it has the disadvantage that (for no compelling reason I can see) it recomputes the step from the first two elements instead of taking the step as an argument, so it can lose a great deal of precision in the step up front.

  • I see. How does this up-front calculation make a difference? – coldspeed Aug 27 '17 at 16:40
  • @cᴏʟᴅsᴘᴇᴇᴅ: Mostly, it's just different, so the results are sometimes different. That happens with floating point. I believe it does involve less rounding error, but you'll sometimes get the "wrong" endpoint anyway. – user2357112 Aug 27 '17 at 16:44
  • If you were to do np.arange(0, 1.1, 0.1).tolist(), you'd get an upper limit of 1.0 instead of 1.09999999999 which I thought was fascinating but from MSeifert's answer is explained by the different mechanism of computing the next item in the range. – coldspeed Aug 27 '17 at 17:14
  • @cᴏʟᴅsᴘᴇᴇᴅ: No, the endpoint difference is due to stopping at a precomputed length instead of stopping when it hits the stop argument. However, if it did stop when it hit the stop argument, the different method of computing elements would also have caused it to stop at 1.0 instead of 1.0999999999999999. – user2357112 Aug 27 '17 at 17:19
  • Optimistically assuming a magic optimizer, recomputing the step allows the optimizer to arrange the computation so that additional bits ("guard bits", e.g.) of precision in the FPU can be retained for the subsequent multiply. If the step is passed to through a stack (or register) those bits can be lost. – Eric Towers Aug 27 '17 at 21:07

While arange does step through the range in a slightly different way, it still has the float representation issue:

In [1358]: np.arange(0,1,0.1)
Out[1358]: array([ 0. ,  0.1,  0.2,  0.3,  0.4,  0.5,  0.6,  0.7,  0.8,  0.9])

The print hides that; convert it to a list to see the gory details:

In [1359]: np.arange(0,1,0.1).tolist()

or with another iteration

In [1360]: [i for i in np.arange(0,1,0.1)]  # e.g. list(np.arange(...))

In this case each displayed item is a np.float64, where as in the first each is float.

  • 1
    The [i for i in ...] comparison isn't fair, because something like 0.10000000000000001 isn't arange's fault; it's exactly equal to the float 0.1, but NumPy is printing it to 17 digits. – user2357112 Aug 27 '17 at 16:58

Aside from the different representation of lists and arrays NumPys arange works by multiplying instead of repeated adding. It's more like:

def my_range2(start, stop, step):
    i = 0
    while start+(i*step) < stop:
        yield start+(i*step)
        i += 1

Then the output is completely equal:

>>> np.arange(0, 1, 0.1).tolist() == list(my_range2(0, 1, 0.1))

With repeated addition you would "accumulate" floating point rounding errors. The multiplication is still affected by rounding but the error doesn't accumulate.

As pointed out in the comments it's not really what is happening. As far as I see it it's more like:

def my_range2(start, stop, step):
    length = math.ceil((stop-start)/step)
    # The next two lines are mostly so the function really behaves like NumPy does
    # Remove them to get better accuracy...
    next = start + step
    step = next - start
    for i in range(length):
        yield start+(i*step)

But not sure if that's exactly right either because there's a lot more going on in NumPy.

  • This is performed by the relevant fill function. While it does prevent accumulation of error, it has the flaw that it recomputes the step from the first two elements instead of receiving the original step as an argument, so it may lose a great deal of precision in the step up front. – user2357112 Aug 27 '17 at 17:12
  • Also, it doesn't stop when it hits the original stop argument; it stops when it hits a precomputed length. – user2357112 Aug 27 '17 at 17:14
  • @user2357112 Oh, I see. It's definetly more complicated than I thought. Seems weird to do it that way ... are you sure that this could lead to precision loss? I mean the first element was computed by adding the step to the start. – MSeifert Aug 27 '17 at 17:39
  • 2
    It can. For example, if the start is 100 and the step argument is 0.1, then computing (100+0.1) - 100 causes NumPy to use an actual step of 0.09999999999999432. This causes numpy.arange(0, 1000, 0.1)[-1] to be significantly more accurate than numpy.arange(100, 1000, 0.1)[-1]. – user2357112 Aug 27 '17 at 17:53
  • Interesting. I wonder if I should fix the implementation to use that "nice" behavior. :D – MSeifert Aug 27 '17 at 17:55

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