# Python: Finding differences between elements of a list

Given a list of numbers, how does one find differences between every (i)-th elements and its (i+1)-th?

Is it better to use a lambda expression or maybe a list comprehension?

For example:

Given a list t=[1,3,6,...], the goal is to find a list v=[2,3,...] because 3-1=2, 6-3=3, etc.

## 12 Answers

>>> t
[1, 3, 6]
>>> [j-i for i, j in zip(t[:-1], t[1:])]  # or use itertools.izip in py2k
[2, 3]

• In case you need absolute differences, [abs(j-i) for i,j in zip(t, t[1:])]
– Anil
Commented Jul 14, 2015 at 0:09
• In case you want to make it more efficient: list(itertools.starmap(operator.sub, zip(t[1:], t))) (after importing itertools and operator). Commented Jun 24, 2018 at 18:31
• Actually simply list(map(operator.sub, t[1:], t[:-1])) will do. Commented Aug 6, 2018 at 15:24

The other answers are correct but if you're doing numerical work, you might want to consider numpy. Using numpy, the answer is:

v = numpy.diff(t)

• Very helpful! Thanks! np.diff([2,4,9]) would be [2,5] Commented Oct 7, 2019 at 20:38
• Would this be more efficient than the zip version? Commented Jul 28, 2020 at 23:29

If you don't want to use numpy nor zip, you can use the following solution:

>>> t = [1, 3, 6]
>>> v = [t[i+1]-t[i] for i in range(len(t)-1)]
>>> v
[2, 3]


Starting in Python 3.10, with the new pairwise function it's possible to slide through pairs of elements and thus map on rolling pairs:

from itertools import pairwise

[y-x for (x, y) in pairwise([1, 3, 6, 7])]
# [2, 3, 1]


The intermediate result being:

pairwise([1, 3, 6, 7])
# [(1, 3), (3, 6), (6, 7)]

• Lol, I've had something similar in my common functions for ages now. I called my implementation "chunker", but pairwise has a nice sound to it. Very useful. Commented Jun 27, 2021 at 21:55

You can use itertools.tee and zip to efficiently build the result:

from itertools import tee
# python2 only:
#from itertools import izip as zip

def differences(seq):
iterable, copied = tee(seq)
next(copied)
for x, y in zip(iterable, copied):
yield y - x


Or using itertools.islice instead:

from itertools import islice

def differences(seq):
nexts = islice(seq, 1, None)
for x, y in zip(seq, nexts):
yield y - x


You can also avoid using the itertools module:

def differences(seq):
iterable = iter(seq)
prev = next(iterable)
for element in iterable:
yield element - prev
prev = element


All these solution work in constant space if you don't need to store all the results and support infinite iterables.

Here are some micro-benchmarks of the solutions:

In [12]: L = range(10**6)

In [13]: from collections import deque
In [15]: %timeit deque(differences_tee(L), maxlen=0)
10 loops, best of 3: 122 ms per loop

In [16]: %timeit deque(differences_islice(L), maxlen=0)
10 loops, best of 3: 127 ms per loop

In [17]: %timeit deque(differences_no_it(L), maxlen=0)
10 loops, best of 3: 89.9 ms per loop


And the other proposed solutions:

In [18]: %timeit [x[1] - x[0] for x in zip(L[1:], L)]
10 loops, best of 3: 163 ms per loop

In [19]: %timeit [L[i+1]-L[i] for i in range(len(L)-1)]
1 loops, best of 3: 395 ms per loop

In [20]: import numpy as np

In [21]: %timeit np.diff(L)
1 loops, best of 3: 479 ms per loop

In [35]: %%timeit
...: res = []
...: for i in range(len(L) - 1):
...:     res.append(L[i+1] - L[i])
...:
1 loops, best of 3: 234 ms per loop


Note that:

• zip(L[1:], L) is equivalent to zip(L[1:], L[:-1]) since zip already terminates on the shortest input, however it avoids a whole copy of L.
• Accessing the single elements by index is very slow because every index access is a method call in python
• numpy.diff is slow because it has to first convert the list to a ndarray. Obviously if you start with an ndarray it will be much faster:

In [22]: arr = np.array(L)

In [23]: %timeit np.diff(arr)
100 loops, best of 3: 3.02 ms per loop

• in the second solution, islice(seq, 1, None) instead of islice(seq, 1, len(seq)) makes it work with infinite iterables Commented May 12, 2018 at 17:12

I would suggest using

v = np.diff(t)


this is simple and easy to read.

But if you want v to have the same length as t then

v = np.diff([t[0]] + t) # for python 3.x


or

v = np.diff(t + [t[-1]])


FYI: this will only work for lists.

for numpy arrays

v = np.diff(np.append(t[0], t))

• nice answer, you can also use the prepend keyword though to ensure the same length, see answer below, which I think is a little neater Commented Apr 23, 2020 at 8:41

Using the := walrus operator available in Python 3.8+:

>>> t = [1, 3, 6]
>>> prev = t[0]; [-prev + (prev := x) for x in t[1:]]
[2, 3]


A functional approach:

>>> import operator
>>> a = [1,3,5,7,11,13,17,21]
>>> map(operator.sub, a[1:], a[:-1])
[2, 2, 2, 4, 2, 4, 4]


Using generator:

>>> import operator, itertools
>>> g1,g2 = itertools.tee((x*x for x in xrange(5)),2)
>>> list(itertools.imap(operator.sub, itertools.islice(g1,1,None), g2))
[1, 3, 5, 7]


Using indices:

>>> [a[i+1]-a[i] for i in xrange(len(a)-1)]
[2, 2, 2, 4, 2, 4, 4]


Ok. I think I found the proper solution:

v = [x[0]-x[1] for x in zip(t[1:],t[:-1])]

• ya its good, but I think it should have been v = [x[0]-x[1] for x in zip(t[1:], t[:-1])] for sorted list! Commented Jan 31, 2016 at 10:38

I suspect this is what the numpy diff command does anyway, but just for completeness you can simply difference the sub-vectors:

from numpy import array as a
a(x[1:])-a(x[:-1])


In addition, I wanted to add these solutions to generalizations of the question:

Solution with periodic boundaries

Sometimes with numerical integration you will want to difference a list with periodic boundary conditions (so the first element calculates the difference to the last. In this case the numpy.roll function is helpful:

v-np.roll(v,1)


Solutions with zero prepended

Another numpy solution (just for completeness) is to use

numpy.ediff1d(v)


This works as numpy.diff, but only on a vector (it flattens the input array). It offers the ability to prepend or append numbers to the resulting vector. This is useful when handling accumulated fields that is often the case fluxes in meteorological variables (e.g. rain, latent heat etc), as you want a resulting list of the same length as the input variable, with the first entry untouched.

Then you would write

np.ediff1d(v,to_begin=v[0])


Of course, you can also do this with the np.diff command, in this case though you need to prepend zero to the series with the prepend keyword:

np.diff(v,prepend=0.0)


All the above solutions return a vector that is the same length as the input.

You can also convert the difference into an easily readable transition matrix using

v = t.reshape((c,r)).T - t.T


Where c = number of items in the list and r = 1 since a list is basically a vector or a 1d array.

My way

>>>v = [1,2,3,4,5]
>>>[v[i] - v[i-1] for i, value in enumerate(v[1:], 1)]
[1, 1, 1, 1]