129

This question contains its own answer at the bottom. Use preallocated arrays.

Following-up from this question years ago, is there a canonical "shift" function in numpy? I don't see anything from the documentation.

Here's a simple version of what I'm looking for:

def shift(xs, n):
    if n >= 0:
        return np.r_[np.full(n, np.nan), xs[:-n]]
    else:
        return np.r_[xs[-n:], np.full(-n, np.nan)]

Using this is like:

In [76]: xs
Out[76]: array([ 0.,  1.,  2.,  3.,  4.,  5.,  6.,  7.,  8.,  9.])

In [77]: shift(xs, 3)
Out[77]: array([ nan,  nan,  nan,   0.,   1.,   2.,   3.,   4.,   5.,   6.])

In [78]: shift(xs, -3)
Out[78]: array([  3.,   4.,   5.,   6.,   7.,   8.,   9.,  nan,  nan,  nan])

This question came from my attempt to write a fast rolling_product yesterday. I needed a way to "shift" a cumulative product and all I could think of was to replicate the logic in np.roll().


So np.concatenate() is much faster than np.r_[]. This version of the function performs a lot better:

def shift(xs, n):
    if n >= 0:
        return np.concatenate((np.full(n, np.nan), xs[:-n]))
    else:
        return np.concatenate((xs[-n:], np.full(-n, np.nan)))

An even faster version simply pre-allocates the array:

def shift(xs, n):
    e = np.empty_like(xs)
    if n >= 0:
        e[:n] = np.nan
        e[n:] = xs[:-n]
    else:
        e[n:] = np.nan
        e[:n] = xs[-n:]
    return e

The above proposal is the answer. Use preallocated arrays.

4
  • wondering if np.r_[np.full(n, np.nan), xs[:-n]] could be replaced with np.r_[[np.nan]*n, xs[:-n]] likewise for other condition, without the need of np.full
    – Zero
    Commented May 22, 2015 at 16:15
  • 2
    @JohnGalt [np.nan]*n is plain python and will therefore be slower than np.full(n, np.nan). Not for small n, but it will be transformed to numpy array by np.r_ which takes away the advantage.
    – swenzel
    Commented May 22, 2015 at 16:39
  • @swenzel Just timed it and [np.nan]*n is faster than np.full(n, np.nan) for n=[10,1000,10000]. Need to check if np.r_ takes a hit.
    – Zero
    Commented May 22, 2015 at 16:46
  • If speed is of concern, the array size plays a huge role for the best algorithm (added a benchmark comparison below). Also, nowadays numba.njit can be used to make the shift faster if called repeatedly.
    – Niko Fohr
    Commented Jul 11, 2020 at 15:30

14 Answers 14

136
+50

Not numpy but scipy provides exactly the shift functionality you want,

import numpy as np
from scipy.ndimage import shift

xs = np.array([ 0.,  1.,  2.,  3.,  4.,  5.,  6.,  7.,  8.,  9.])

shift(xs, 3, cval=np.NaN)

where default is to bring in a constant value from outside the array with value cval, set here to nan. This gives the desired output,

array([ nan, nan, nan, 0., 1., 2., 3., 4., 5., 6.])

and the negative shift works similarly,

shift(xs, -3, cval=np.NaN)

Provides output

array([  3.,   4.,   5.,   6.,   7.,   8.,   9.,  nan,  nan,  nan])
5
  • 35
    The scipy shift function is REALLY slow. I rolled my own using np.concatenate and it was much faster.
    – minou
    Commented Oct 16, 2015 at 23:32
  • 20
    numpy.roll is faster. pandas also uses it. github.com/pandas-dev/pandas/blob/v0.19.2/pandas/core/…
    – kirin
    Commented Jan 25, 2017 at 1:06
  • 2
    Just tested the scipy.ndimage.interpolation.shift (scipy 1.4.1) against all the other alternatives listed on this page (see my answer below), and this is the slowest possible solution. Use only if speed is of no importance in your application.
    – Niko Fohr
    Commented Jul 11, 2020 at 15:25
  • from scipy.ndimage.interpolation import shift was deprecated. Now, simply use from scipy.ndimage import shift Commented Sep 23, 2022 at 6:07
  • One nice feature about interpolation.shift though is that it supports multidimensional arrays. For a 2D array, you would need to do shift(xs, (3,0), cval=np.NaN) instead of just 3 as in 1D. Commented Feb 11, 2023 at 13:09
122

For those who want to just copy and paste the fastest implementation of shift, there is a benchmark and conclusion(see the end). In addition, I introduce fill_value parameter and fix some bugs.

Benchmark

import numpy as np
import timeit

# enhanced from IronManMark20 version
def shift1(arr, num, fill_value=np.nan):
    arr = np.roll(arr,num)
    if num < 0:
        arr[num:] = fill_value
    elif num > 0:
        arr[:num] = fill_value
    return arr

# use np.roll and np.put by IronManMark20
def shift2(arr,num):
    arr=np.roll(arr,num)
    if num<0:
         np.put(arr,range(len(arr)+num,len(arr)),np.nan)
    elif num > 0:
         np.put(arr,range(num),np.nan)
    return arr

# use np.pad and slice by me.
def shift3(arr, num, fill_value=np.nan):
    l = len(arr)
    if num < 0:
        arr = np.pad(arr, (0, abs(num)), mode='constant', constant_values=(fill_value,))[:-num]
    elif num > 0:
        arr = np.pad(arr, (num, 0), mode='constant', constant_values=(fill_value,))[:-num]

    return arr

# use np.concatenate and np.full by chrisaycock
def shift4(arr, num, fill_value=np.nan):
    if num >= 0:
        return np.concatenate((np.full(num, fill_value), arr[:-num]))
    else:
        return np.concatenate((arr[-num:], np.full(-num, fill_value)))

# preallocate empty array and assign slice by chrisaycock
def shift5(arr, num, fill_value=np.nan):
    result = np.empty_like(arr)
    if num > 0:
        result[:num] = fill_value
        result[num:] = arr[:-num]
    elif num < 0:
        result[num:] = fill_value
        result[:num] = arr[-num:]
    else:
        result[:] = arr
    return result

arr = np.arange(2000).astype(float)

def benchmark_shift1():
    shift1(arr, 3)

def benchmark_shift2():
    shift2(arr, 3)

def benchmark_shift3():
    shift3(arr, 3)

def benchmark_shift4():
    shift4(arr, 3)

def benchmark_shift5():
    shift5(arr, 3)

benchmark_set = ['benchmark_shift1', 'benchmark_shift2', 'benchmark_shift3', 'benchmark_shift4', 'benchmark_shift5']

for x in benchmark_set:
    number = 10000
    t = timeit.timeit('%s()' % x, 'from __main__ import %s' % x, number=number)
    print '%s time: %f' % (x, t)

benchmark result:

benchmark_shift1 time: 0.265238
benchmark_shift2 time: 0.285175
benchmark_shift3 time: 0.473890
benchmark_shift4 time: 0.099049
benchmark_shift5 time: 0.052836

Conclusion

shift5 is winner! It's OP's third solution.

7
  • Thanks for the comparisons. Any idea what is the fastest way to do it without using a new array?
    – FiReTiTi
    Commented Apr 12, 2017 at 22:21
  • 2
    In the last clause of shift5 it's better to write result[:] = arr instead of result = arr, to keep function behavior consistent.
    – avysk
    Commented Dec 23, 2017 at 14:19
  • 3
    This should be chosed as an answer
    – wyx
    Commented Mar 13, 2018 at 8:44
  • 1
    @gzx, I haven't checked all of the suggestions, but forshift5, I ended up adding arr = arr.astype(float). I tried the function with an array on integers but got ValueError: cannot convert float NaN to integer
    – Josmoor98
    Commented Sep 19, 2019 at 15:56
  • 2
    @Josmoor98 That's because type(np.NAN) is float. If you shift integer array using these functions, you need to specify a integer fill_value.
    – gzc
    Commented Sep 23, 2019 at 9:46
30

Benchmarks & introducing Numba

1. Summary

  • The accepted answer (scipy.ndimage.interpolation.shift) is the slowest solution listed in this page.
  • Numba (@numba.njit) gives some performance boost when array size smaller than ~25.000
  • "Any method" equally good when array size large (>250.000).
  • The fastest option really depends on
        (1)  Length of your arrays
        (2)  Amount of shift you need to do.
  • Below is the picture of the timings of all different methods listed on this page (2020-07-11), using constant shift = 10. As one can see, with small array sizes some methods are use more than +2000% time than the best method.

Relative timings, constant shift (10), all methods

2. Detailed benchmarks with the best options

  • Choose shift4_numba (defined below) if you want good all-arounder

Relative timings, best methods (Benchmarks)

3. Code

3.1 shift4_numba

  • Good all-arounder; max 20% wrt. to the best method with any array size
  • Best method with medium array sizes: ~ 500 < N < 20.000.
  • Caveat: Numba jit (just in time compiler) will give performance boost only if you are calling the decorated function more than once. The first call takes usually 3-4 times longer than the subsequent calls. You can get even more performance boost with ahead of time compiled numba.
import numba

@numba.njit
def shift4_numba(arr, num, fill_value=np.nan):
    if num >= 0:
        return np.concatenate((np.full(num, fill_value), arr[:-num]))
    else:
        return np.concatenate((arr[-num:], np.full(-num, fill_value)))

3.2. shift5_numba

  • Best option with small (N <= 300.. 1500) array sizes. Treshold depends on needed amount of shift.
  • Good performance on any array size; max + 50% compared to the fastest solution.
  • Caveat: Numba jit (just in time compiler) will give performance boost only if you are calling the decorated function more than once. The first call takes usually 3-4 times longer than the subsequent calls. You can get even more performance boost with ahead of time compiled numba.
import numba

@numba.njit
def shift5_numba(arr, num, fill_value=np.nan):
    result = np.empty_like(arr)
    if num > 0:
        result[:num] = fill_value
        result[num:] = arr[:-num]
    elif num < 0:
        result[num:] = fill_value
        result[:num] = arr[-num:]
    else:
        result[:] = arr
    return result

3.3. shift5

  • Best method with array sizes ~ 20.000 < N < 250.000
  • Same as shift5_numba, just remove the @numba.njit decorator.

4 Appendix

4.1 Details about used methods

  • shift_scipy: scipy.ndimage.interpolation.shift (scipy 1.4.1) - The option from accepted answer, which is clearly the slowest alternative.
  • shift1: np.roll and out[:num] xnp.nan by IronManMark20 & gzc
  • shift2: np.roll and np.put by IronManMark20
  • shift3: np.pad and slice by gzc
  • shift4: np.concatenate and np.full by chrisaycock
  • shift5: using two times result[slice] = x by chrisaycock
  • shift#_numba: @numba.njit decorated versions of the previous.

The shift2 and shift3 contained functions that were not supported by the current numba (0.50.1).

4.2 Other test results

4.2.1 Relative timings, all methods

4.2.2 Raw timings, all methods

4.2.3 Raw timings, few best methods

11

There is no single function that does what you want. Your definition of shift is slightly different than what most people are doing. The ways to shift an array are more commonly looped:

>>>xs=np.array([1,2,3,4,5])
>>>shift(xs,3)
array([3,4,5,1,2])

However, you can do what you want with two functions.
Consider a=np.array([ 0., 1., 2., 3., 4., 5., 6., 7., 8., 9.]):

def shift2(arr,num):
    arr=np.roll(arr,num)
    if num<0:
         np.put(arr,range(len(arr)+num,len(arr)),np.nan)
    elif num > 0:
         np.put(arr,range(num),np.nan)
    return arr
>>>shift2(a,3)
[ nan  nan  nan   0.   1.   2.   3.   4.   5.   6.]
>>>shift2(a,-3)
[  3.   4.   5.   6.   7.   8.   9.  nan  nan  nan]

After running cProfile on your given function and the above code you provided, I found that the code you provided makes 42 function calls while shift2 made 14 calls when arr is positive and 16 when it is negative. I will be experimenting with timing to see how each performs with real data.

2
  • 1
    Hey, thanks for taking a look at this. I know about np.roll(); I used the technique in the links in my question. As for your implementation, any chance you can get your function to work for negative shift values? Commented May 22, 2015 at 16:54
  • Interestingly, np.concatenate() is a lot faster than np.r_[]. The former is what np.roll() uses, after all. Commented May 22, 2015 at 17:00
7

You can convert ndarray to Series or DataFrame with pandas first, then you can use shift method as you want.

Example:

In [1]: from pandas import Series

In [2]: data = np.arange(10)

In [3]: data
Out[3]: array([0, 1, 2, 3, 4, 5, 6, 7, 8, 9])

In [4]: data = Series(data)

In [5]: data
Out[5]: 
0    0
1    1
2    2
3    3
4    4
5    5
6    6
7    7
8    8
9    9
dtype: int64

In [6]: data = data.shift(3)

In [7]: data
Out[7]: 
0    NaN
1    NaN
2    NaN
3    0.0
4    1.0
5    2.0
6    3.0
7    4.0
8    5.0
9    6.0
dtype: float64

In [8]: data = data.values

In [9]: data
Out[9]: array([ nan,  nan,  nan,   0.,   1.,   2.,   3.,   4.,   5.,   6.])
0
6

You can also do this with Pandas:

Using a 2356-long array:

import numpy as np

xs = np.array([...])

Using scipy:

from scipy.ndimage.interpolation import shift

%timeit shift(xs, 1, cval=np.nan)
# 956 µs ± 77.9 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)

Using Pandas:

import pandas as pd

%timeit pd.Series(xs).shift(1).values
# 377 µs ± 9.42 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)

In this example, using Pandas was about ~8 times faster than Scipy

1
  • 4
    The fastest method is the pre-allocation that I posted at the end of my question. Your Series technique took 146 us on my computer, whereas my approach took under 4 us. Commented Jun 25, 2019 at 14:37
2

If you want a one-liner from numpy and aren't too concerned about performance, try:

np.sum(np.diag(the_array,1),0)[:-1]

Explanation: np.diag(the_array,1) creates a matrix with your array one-off the diagonal, np.sum(...,0) sums the matrix column-wise, and ...[:-1] takes the elements that would correspond to the size of the original array. Playing around with the 1 and :-1 as parameters can give you shifts in different directions.

2

Maybe np.roll is what you need

arr = np.arange(10)
shift = 2  # shift length
arr_1 = np.roll(arr, shift=shift)
arr_1[:shift] = np.nan
1
  • I answered my own question. See the last version that pre-allocates the array. Also, np.roll is already suggested in this answer. Commented Apr 21, 2021 at 11:28
2

A simple and effective way supporting numba and negative shift values like Pandas library. It prevents corrupting the original array in arguments, and also works with an integer array:

import numpy as np
from numba import njit

@njit
def numba_shift(arr_: np.ndarray, shift: np.int32 = 1) -> np.ndarray:
    arr = arr_.copy().astype(np.float64)
    if shift > 0:
        arr[shift:] = arr[:-shift]
        arr[:shift] = np.nan
    else:
        arr[:shift] = arr[-shift:]
        arr[shift:] = np.nan
    return arr

Example:

ar = np.array([1,2,3,4,5,6])
numba_shift(ar,-1)

    array([ 2.,  3.,  4.,  5.,  6., nan])

Timeit:

%timeit numba_shift(ar,-1)

1.02 µs ± 9.42 ns per loop (mean ± std. dev. of 7 runs, 1000000 loops each)

Note: if you dont need numba, just with numpy, then delete the line @njit and the numba import.

0
0

My solution involves np.roll and masked arrays:

import numpy as np
import numpy.ma as ma # this is for masked array

def shift(arr, shift):
    r_arr = np.roll(arr, shift=shift)
    m_arr = ma.masked_array(r_arr,dtype=float)
    if shift > 0: m_arr[:shift] = ma.masked
    else: m_arr[shift:] = ma.masked
    return m_arr.filled(np.nan)

Basically, I just use np.roll to shift the array, then use ma.masked_array to mark the unwanted elements as invalid, and fill those invalid positions with np.nan. I set the dtype to float so that filling with np.nan wouldn't cause any problems.

In [11]: shift(arr, 3)
Out[11]: array([nan, nan, nan,  0.,  1.,  2.,  3.,  4.,  5.,  6.])

In [12]: shift(arr, -3)
Out[12]: array([ 3.,  4.,  5.,  6.,  7.,  8.,  9., nan, nan, nan])
0

Here is a generalization of the fast answer (shift5) to support arbitrary multidimensional arrays:

def shift(array, offset, constant_values=0):
  """Returns copy of array shifted by offset, with fill using constant."""
  array = np.asarray(array)
  offset = np.atleast_1d(offset)
  assert len(offset) == array.ndim
  new_array = np.empty_like(array)

  def slice1(o):
    return slice(o, None) if o >= 0 else slice(0, o)

  new_array[tuple(slice1(o) for o in offset)] = (
      array[tuple(slice1(-o) for o in offset)])

  for axis, o in enumerate(offset):
    new_array[(slice(None),) * axis +
              (slice(0, o) if o >= 0 else slice(o, None),)] = constant_values

  return new_array
0

Here's a solution for two dimensions that's not using special built-in-functions from numpy and thus is compatible with numba.

def shift(array, dy, dx):
    n, m = array.shape[:2]
    e = np.zeros((n, m))
    if dy > 0 and dx > 0:
        e[dy:, dx:] = array[:-dy, :-dx]
        return e
    elif dy > 0 and dx < 0:
        e[dy:, :dx] = array[:-dy, -dx:]
        return e
    elif dy < 0 and dx > 0:
        e[:dy, dx:] = array[-dy:, :-dx]
        return e
    elif dy < 0 and dx < 0:
        e[:dy, :dx] = array[-dy:, -dx:]
        return e
    elif dy < 0 and dx == 0:
        e[:dy, :] = array[-dy:, :]
        return e
    elif dy > 0 and dx == 0:
        e[dy:, :] = array[:-dy, :]
        return e
    elif dy == 0 and dx < 0:
        e[:, :dx] = array[:, -dx:]
        return e
    elif dy == 0 and dx > 0:
        e[:, dx:] = array[:, :-dx]
        return e
-1

I think I have a quicker solution: why don't just use deque ? I added 2 benchmark to the benchmarked solution from @gzc:

def shift6(arr, num, fill_value=np.nan):
    for _ in range(num):
        darr.appendleft(fill_value)

def shift7(arr, num, fill_value=np.nan):
    darr = deque(arr)
    for _ in range(num):
        darr.appendleft(fill_value)

darr = deque(arr)

def benchmark_shift6():
    shift6(arr, 3)
    
def benchmark_shift7():
    shift6(arr, 3)

benchmark_set = ['benchmark_shift1', 'benchmark_shift2', 'benchmark_shift3', 'benchmark_shift4', 'benchmark_shift5', 'benchmark_shift6', 'benchmark_shift7']

And on my laptop the output is a lot of better than any other solutions proposed:

%s time: ('benchmark_shift1', 0.08232757700170623) 
%s time: ('benchmark_shift2', 0.0934765400015749) 
%s time: ('benchmark_shift3', 0.14349375600431813) 
%s time: ('benchmark_shift4', 0.03575193700089585) 
%s time: ('benchmark_shift5', 0.01389261399890529) 
%s time: ('benchmark_shift6', 0.0025887360025080852) 
%s time: ('benchmark_shift7', 0.0024806019937386736)
3
  • There is a fatal error in your code. Your benchmark_shift7() calls shift6() when it is supposed to call shift7(). Correcting this shows that using a deque by far the slowest operation. Also, your benchmark_shift6() isn't believable because it creates the deque outside of the benchmark! Commented Feb 6, 2022 at 15:48
  • You're right about the benchmark for the test with deque creation: my mistake. Also if deque are chosen by design and it doesn't need the conversion , it's the fastest solution of all proposed answer ! Try to be creative when you code :)
    – alEx
    Commented Feb 7, 2022 at 7:44
  • The question is literally about numpy arrays. "Use something completely unlike numpy arrays" is not an answer. Commented Feb 7, 2022 at 12:47
-2

One way to do it without spilt the code into cases

with array:

def shift(arr, dx, default_value):
    result = np.empty_like(arr)
    get_neg_or_none = lambda s: s if s < 0 else None
    get_pos_or_none = lambda s: s if s > 0 else None
    result[get_neg_or_none(dx): get_pos_or_none(dx)] = default_value
    result[get_pos_or_none(dx): get_neg_or_none(dx)] = arr[get_pos_or_none(-dx): get_neg_or_none(-dx)]     
    return result

with matrix it can be done like this:

def shift(image, dx, dy, default_value):
    res = np.full_like(image, default_value)

    get_neg_or_none = lambda s: s if s < 0 else None
    get_pos_or_none = lambda s : s if s > 0 else None

    res[get_pos_or_none(-dy): get_neg_or_none(-dy), get_pos_or_none(-dx): get_neg_or_none(-dx)] = \
        image[get_pos_or_none(dy): get_neg_or_none(dy), get_pos_or_none(dx): get_neg_or_none(dx)]
    return res
1
  • 1
    This is neither clean nor fast. Commented Dec 21, 2019 at 19:55

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