Interleaving two NumPy arrays efficiently

Assume the following arrays are given:

``````a = array([1, 3, 5])
b = array([2, 4, 6])
``````

How would one interleave them efficiently so that one gets a third array like the following?

``````c = array([1, 2, 3, 4, 5, 6])
``````

It can be assumed that `length(a) == length(b)`.

• How about, same question, but you are trying to interleave matrices. That is a and b are 3 dimensional, and not necessarily the same size in the first dimension. Note:Only the first dimension should be interleaved. Nov 17, 2017 at 21:29
• adding a comment for anyone trying to search "translate Wolfram Mathematica's Riffle to Python" and not finding anything. hope this was picked up by your search engine Sep 5, 2022 at 16:59

I like Josh's answer. I just wanted to add a more mundane, usual, and slightly more verbose solution. I don't know which is more efficient. I expect they will have similar performance.

``````import numpy as np

a = np.array([1,3,5])
b = np.array([2,4,6])

c = np.empty((a.size + b.size,), dtype=a.dtype)
c[0::2] = a
c[1::2] = b
``````
• Unless speed is really really important, I would go with this as it's much more comprehensible which is important if anyone is ever going to look at it again. Mar 18, 2011 at 3:02
• +1 I played around with timings and your code surprisingly seems to be 2-5x faster depending on inputs. I still find the efficiency of these types of operations to be nonintuitive, so it's always worth it to use `timeit` to test things out if a particular operation is a bottleneck in your code. There are usually more than one way to do things in numpy, so definitely profile code snippets. Mar 18, 2011 at 3:04
• @JoshAdel: I guess if `.reshape` creates an additional copy of the array, then that would explain a 2x performance hit. I don't think it always makes a copy, however. I'm guessing the 5x difference is only for small arrays?
– Paul
Mar 18, 2011 at 3:39
• looking at `.flags` and testing `.base` for my solution, it looks like the reshape to 'F' format creates a hidden copy of the vstacked data, so it's not a simple view as I thought it would be. And strangely the 5x is only for intermediate sized arrays for some reason. Mar 18, 2011 at 14:52
• Another advantage of this answer is it's not limited to arrays of the same length. It could weave `n` items with `n-1` items. Sep 25, 2019 at 11:48

I thought it might be worthwhile to check how the solutions performed in terms of performance. And this is the result:

This clearly shows that the most upvoted and accepted answer (Paul's answer) is also the fastest option.

The code was taken from the other answers and from another Q&A:

``````# Setup
import numpy as np

def Paul(a, b):
c = np.empty((a.size + b.size,), dtype=a.dtype)
c[0::2] = a
c[1::2] = b
return c

return np.vstack((a,b)).reshape((-1,),order='F')

def xioxox(a, b):
return np.ravel(np.column_stack((a,b)))

def Benjamin(a, b):
return np.vstack((a,b)).ravel([-1])

def andersonvom(a, b):
return np.hstack(zip(a,b))

def bhanukiran(a, b):
return np.dstack((a,b)).flatten()

def Tai(a, b):
return np.insert(b, obj=range(a.shape[0]), values=a)

def Will(a, b):
return np.ravel((a,b), order='F')

# Timing setup
timings = {Paul: [], JoshAdel: [], xioxox: [], Benjamin: [], andersonvom: [], bhanukiran: [], Tai: [], Will: []}
sizes = [2**i for i in range(1, 20, 2)]

# Timing
for size in sizes:
func_input1 = np.random.random(size=size)
func_input2 = np.random.random(size=size)
for func in timings:
res = %timeit -o func(func_input1, func_input2)
timings[func].append(res)

%matplotlib notebook

import matplotlib.pyplot as plt
import numpy as np

fig = plt.figure(1)
ax = plt.subplot(111)

for func in timings:
ax.plot(sizes,
[time.best for time in timings[func]],
label=func.__name__)  # you could also use "func.__name__" here instead
ax.set_xscale('log')
ax.set_yscale('log')
ax.set_xlabel('size')
ax.set_ylabel('time [seconds]')
ax.grid(which='both')
ax.legend()
plt.tight_layout()
``````

Just in case you have numba available you could also use that to create a function:

``````import numba as nb

@nb.njit
def numba_interweave(arr1, arr2):
res = np.empty(arr1.size + arr2.size, dtype=arr1.dtype)
for idx, (item1, item2) in enumerate(zip(arr1, arr2)):
res[idx*2] = item1
res[idx*2+1] = item2
return res
``````

It could be slightly faster than the other alternatives:

• Also of note, the accepted answer is way faster than the a native Python solution with `roundrobin()` from the itertools recipes. Jan 28, 2018 at 17:41
• As per the chart, Paul's answer appears to be the slowest as the size of the data increases. However, @MSeifert says that 'This clearly shows that the most upvoted and accepted answer (Pauls answer) is also the fastest option.' Given MSeifert's statement, I believe I am reading the chart wrong. Could you please clarify? Feb 10 at 3:34
• @user3613932 Pauls answer is the blue line. And regarding the interpretation: Lower means faster. The blue and the yellow-greenish line (numba/Paul) are lowest and therefore fastest. The pink and purple (Tai and andersonvom) are highest and therefore slowest. I agree that the line colors are not really easy to differentiate but you should be able to easily reproduce the graph with the given code. Feb 15 at 15:31
• Nice plot. Can you share to us how to call the benchmark with the `Timing setup` as the input, also the `plot` function? Thank you. Feb 21 at 10:41
• @MuhammadYasirroni I don't know what you mean. The code in this answer should be runnable as-is (in a jupyter notebook environment at least). :) Feb 23 at 9:00

Here is a one-liner:

``````c = numpy.vstack((a,b)).reshape((-1,),order='F')
``````
• Wow, this is so unreadable :) This is one of the cases where if you don't write a proper comment in the code, it can drive somebody crazy. Mar 18, 2011 at 1:26
• It's just two common numpy commands strung together. I wouldn't think it is that unreadable, although a comment never hurts. Mar 18, 2011 at 1:31
• @JohnAdel, well, it's not `numpy.vstack((a,b)).interweave()` :) Mar 18, 2011 at 13:52
• @Ilya: I would have called the function `.interleave()` personally :) Mar 18, 2011 at 14:53
• What does `reshape` do? May 19, 2017 at 11:23

Here is a simpler answer than some of the previous ones

``````import numpy as np
a = np.array([1,3,5])
b = np.array([2,4,6])
inter = np.ravel(np.column_stack((a,b)))
``````

After this `inter` contains:

``````array([1, 2, 3, 4, 5, 6])
``````

This answer also appears to be marginally faster:

``````In [4]: %timeit np.ravel(np.column_stack((a,b)))
100000 loops, best of 3: 6.31 µs per loop

In [8]: %timeit np.ravel(np.dstack((a,b)))
100000 loops, best of 3: 7.14 µs per loop

In [11]: %timeit np.vstack((a,b)).ravel([-1])
100000 loops, best of 3: 7.08 µs per loop
``````

This will interleave/interlace the two arrays and I believe it is quite readable:

``````a = np.array([1,3,5])      #=> array([1, 3, 5])
b = np.array([2,4,6])      #=> array([2, 4, 6])
c = np.hstack( zip(a,b) )  #=> array([1, 2, 3, 4, 5, 6])
``````
• I like this one as most readable. despite the fact that it is the slowest solution. Dec 6, 2019 at 9:31
• Wrap `zip` in a `list` to avoid depreciation warning Sep 21, 2020 at 17:28

``````import numpy as np

a = np.array([1,3,5])
b = np.array([2,4,6])
inter = np.ravel((a,b), order='F')
``````

I needed to do this but with multidimensional arrays along any axis. Here's a quick general purpose function to that effect. It has the same call signature as `np.concatenate`, except that all input arrays must have exactly the same shape.

``````import numpy as np

def interleave(arrays, axis=0, out=None):
shape = list(np.asanyarray(arrays[0]).shape)
if axis < 0:
axis += len(shape)
assert 0 <= axis < len(shape), "'axis' is out of bounds"
if out is not None:
out = out.reshape(shape[:axis+1] + [len(arrays)] + shape[axis+1:])
shape[axis] = -1
return np.stack(arrays, axis=axis+1, out=out).reshape(shape)
``````
• +1 for such a generalized recipe (works with n-dim, interleaves along any axis, works for any number of input arrays, takes an optional `out` arg, and works for sub-classed arrays). Personally, I would prefer `axis` to default to `-1` rather than to `0`, but maybe that's just me. And you might want to link to this answer of yours, from this question, which actually asked for the input arrays to be n-dimensional. Dec 2, 2020 at 0:11

``````c = numpy.vstack((a,b)).ravel([-1])
``````
• `ravel`'s `order` argument in the documentation is one of `C`, `F`, `A`, or `K`. I think you really want `.ravel('F')`, for FORTRAN order (column first) Feb 11, 2014 at 18:10

`vstack` sure is an option, but a more straightforward solution for your case could be the `hstack`:

``````a = array([1,3,5])
b = array([2,4,6])
hstack((a,b)) # Remember it is a tuple of arrays that this function swallows in.
array([1, 3, 5, 2, 4, 6])
sort(hstack((a,b)))
array([1, 2, 3, 4, 5, 6])
``````

And more importantly this works for arbitrary shapes of `a` and `b`.

Also you may want to try out `dstack`:

``````a = array([1,3,5])
b = array([2,4,6])
dstack((a,b)).flatten()
array([1, 2, 3, 4, 5, 6])
``````

You’ve got options now!

• -1 to first answer because question has nothing to do with sorting. +1 to second answer, which is the best I've seen so far. This is why multiple solutions should be posted as multiple answers. Please split it into multiple answers. Jan 16, 2013 at 17:57

Another one-liner: `np.vstack((a,b)).T.ravel()`
One more: `np.stack((a,b),1).ravel()`

One can also try `np.insert` (the solution was migrated from Interleave NumPy arrays).

``````import numpy as np

a = np.array([1,3,5])
b = np.array([2,4,6])
np.insert(b, obj=range(a.shape[0]), values=a)
``````

Another one-liner:

``````>>> c = np.array([a, b]).T.flatten()
>>> c
array([1, 2, 3, 4, 5, 6])
``````

For 2D numpy array:

``````def interleave2d(a, b):
"""Interleave between columns of two arrays"""
c = np.empty((len(a), a.shape[1] * 2), dtype=a.dtype)
c[:, 0::2] = a
c[:, 1::2] = b
return c
``````

Not the prettiest function, but I needed one that could interleave an arbitrary number of matrices. Maybe helpful?

`````` def interleave_narr(*args):
''' Given N numpy arrays, interleave arr i+1...i+N'''
m_sizes = 0
for m in args:
m_sizes += m.size
o = np.empty((m_sizes,), dtype=args[0].dtype)

n_mats = len(args)
for ii in range(n_mats):
o[ii::n_mats] = args[ii]
return o
``````