# How to find the cumulative sum of numbers in a list?

``````time_interval = [4, 6, 12]
``````

I want to sum up the numbers like `[4, 4+6, 4+6+12]` in order to get the list `t = [4, 10, 22]`.

I tried the following:

``````t1 = time_interval[0]
t2 = time_interval[1] + t1
t3 = time_interval[2] + t2
print(t1, t2, t3)  # -> 4 10 22
``````

If you're doing much numerical work with arrays like this, I'd suggest `numpy`, which comes with a cumulative sum function `cumsum`:

``````import numpy as np

a = [4,6,12]

np.cumsum(a)
#array([4, 10, 22])
``````

Numpy is often faster than pure python for this kind of thing, see in comparison to @Ashwini's `accumu`:

``````In [136]: timeit list(accumu(range(1000)))
10000 loops, best of 3: 161 us per loop

In [137]: timeit list(accumu(xrange(1000)))
10000 loops, best of 3: 147 us per loop

In [138]: timeit np.cumsum(np.arange(1000))
100000 loops, best of 3: 10.1 us per loop
``````

But of course if it's the only place you'll use numpy, it might not be worth having a dependence on it.

• This should have a `np.cumsun` case that starts with a list, to take into account the conversion time. Aug 20, 2016 at 14:56
• Good point @hpaulj, for those starting from (or aiming for) a `list` I would not recommend `numpy`. Aug 23, 2016 at 19:09
• I don't think numpy is fastest stackoverflow.com/questions/15889131/… Sep 16, 2016 at 15:18
• Agreed, as I mentioned above. Avoiding reactions like yours and @hpaulj's is why I tried to limit its scope in the very first and last lines of my answer :-/ Sep 16, 2016 at 15:54
• @alex: Using `timeit`, "if `-n` is not given, a suitable number of loops is calculated by trying successive powers of 10 until the total time is at least 0.2 seconds." If you expect it to make a difference, you can supply `-n 1000` to make them all equivalent. Jun 13, 2018 at 18:23

In Python 2 you can define your own generator function like this:

``````def accumu(lis):
total = 0
for x in lis:
total += x
yield total

In [4]: list(accumu([4,6,12]))
Out[4]: [4, 10, 22]
``````

And in Python 3.2+ you can use `itertools.accumulate()`:

``````In [1]: lis = [4,6,12]

In [2]: from itertools import accumulate

In [3]: list(accumulate(lis))
Out[3]: [4, 10, 22]
``````
• PEP 572 -- Assignment Expressions (expected for Python 3.8) shows an interesting alternative `total = 0; partial_sums = [total := total + v for v in values]`. I would still expect `accumulate` to be faster. Jul 15, 2018 at 16:46
• @StevenRumbalski Man, I personally think that's the worst PEP ever. Bad enough... Jul 15, 2018 at 23:10
• @AshwiniChaudhary: This example may let the PEP look worse than it is. It has some quite readable and very useful applications. For instance, `if (value := some_dict.get(key)) is not None: ...` which avoids the notorious double lookup. Or also in list comprehensions with an `if` filter like `[func_result for x in xs if satisfies_property(func_result := f(x))]` which also avoids the notorious double evaluation of the function `f(x)`. Jun 25, 2022 at 20:35

Try the `itertools.accumulate()` function.

``````import itertools

list(itertools.accumulate([1,2,3,4,5]))
# [1, 3, 6, 10, 15]
``````
• You don't need to to pass `operator.add` as the default operation is addition anyway. Mar 23, 2019 at 18:18

I did a bench-mark of the top two answers with Python 3.4 and I found `itertools.accumulate` is faster than `numpy.cumsum` under many circumstances, often much faster. However, as you can see from the comments, this may not always be the case, and it's difficult to exhaustively explore all options. (Feel free to add a comment or edit this post if you have further benchmark results of interest.)

Some timings...

For short lists `accumulate` is about 4 times faster:

``````from timeit import timeit

def sum1(l):
from itertools import accumulate
return list(accumulate(l))

def sum2(l):
from numpy import cumsum
return list(cumsum(l))

l = [1, 2, 3, 4, 5]

timeit(lambda: sum1(l), number=100000)
# 0.4243644131347537
timeit(lambda: sum2(l), number=100000)
# 1.7077815784141421
``````

For longer lists `accumulate` is about 3 times faster:

``````l = [1, 2, 3, 4, 5]*1000
timeit(lambda: sum1(l), number=100000)
# 19.174508565105498
timeit(lambda: sum2(l), number=100000)
# 61.871223849244416
``````

If the `numpy` `array` is not cast to `list`, `accumulate` is still about 2 times faster:

``````from timeit import timeit

def sum1(l):
from itertools import accumulate
return list(accumulate(l))

def sum2(l):
from numpy import cumsum
return cumsum(l)

l = [1, 2, 3, 4, 5]*1000

print(timeit(lambda: sum1(l), number=100000))
# 19.18597290944308
print(timeit(lambda: sum2(l), number=100000))
# 37.759664884768426
``````

If you put the imports outside of the two functions and still return a `numpy` `array`, `accumulate` is still nearly 2 times faster:

``````from timeit import timeit
from itertools import accumulate
from numpy import cumsum

def sum1(l):
return list(accumulate(l))

def sum2(l):
return cumsum(l)

l = [1, 2, 3, 4, 5]*1000

timeit(lambda: sum1(l), number=100000)
# 19.042188624851406
timeit(lambda: sum2(l), number=100000)
# 35.17324400227517
``````
• You wouldn't expect an airplane to be faster than the train to travel across town, especially including ticket purchase and security screening. Likewise you wouldn't use numpy to process a `list` of five items, especially if you are unwilling to accept an `array` in return. If the list in question is really so short, then their running time would be inconsequential---dependencies and legibility would surely dominate. But wide usage of a `list` of uniform numerical data type of significant length would be silly; for that, a numpy `array` would be appropriate, and usually faster. Sep 16, 2016 at 16:07
• @askewchan well I don't just find this for short lists and the OP's question asks for a list as output rather than a numpy array. Perhaps you can edit your answer to be clearer on when each use is appropriate :) Sep 16, 2016 at 16:23
• @askewchan In fact I've edited my answer with a much more detailed comparison. Under no circumstances, do I find `numpy` to be faster, unless I've overlooked something? Sep 16, 2016 at 18:12
• Oh my, yes indeed :) I wouldn't say you've overlooked something, but the comparison is hard to make in isolation without considering your inputs and outputs. Most of the time in your `sum2` function is probably in converting `l` into an array. Try timing `a = np.array(l)` and `np.cumsum(a)` separately. Then try `a = np.tile(np.arange(1, 6), 1000)` vs `l = [1,2,3,4,5]*1000`. In a program conducting other numerical processes (like the creation or loading of `l` in the first place) your working data would probably be in an array already, and the creation would be a constant cost. Sep 16, 2016 at 18:39
• @askewchan I got the same idea as you and therefore I did time the a = np.array(l). For the sum2 without the transformation to list, and with a numpy array as input, sum2 is 5 times faster thank sum1 in my computer in case of the long list/array. Mar 24, 2017 at 15:47

Behold:

``````a = [4, 6, 12]
reduce(lambda c, x: c + [c[-1] + x], a, [0])[1:]
``````

Will output (as expected):

``````[4, 10, 22]
``````
• Not efficient. The total expense of performing `c + [c[-1] + x]` over and over adds up to a total runtime quadratic in the input length. May 22, 2017 at 16:36
• reduce is good for a one-off cumulative sum, but if you're doing a lot of calls to your cumsum function a generator will be useful to "preprocess" your cumulative_sum values and access them in O(1) for each subsequent call. Jul 1, 2017 at 14:06

Assignment expressions from PEP 572 (new in Python 3.8) offer yet another way to solve this:

``````time_interval = [4, 6, 12]

total_time = 0
cum_time = [total_time := total_time + t for t in time_interval]
``````

You can calculate the cumulative sum list in linear time with a simple `for` loop:

``````def csum(lst):
s = lst.copy()
for i in range(1, len(s)):
s[i] += s[i-1]
return s

time_interval = [4, 6, 12]
print(csum(time_interval))  # [4, 10, 22]
``````

The standard library's `itertools.accumulate` may be a faster alternative (since it's implemented in C):

``````from itertools import accumulate
time_interval = [4, 6, 12]
print(list(accumulate(time_interval)))  # [4, 10, 22]
``````

Since python 3.8 it's possible to use Assignment expressions, so things like this became easier to implement

``````nums = list(range(1, 10))
print(f'array: {nums}')

v = 0
cumsum = [v := v + n for n in nums]
print(f'cumsum: {cumsum}')
``````

produces

``````array: [1, 2, 3, 4, 5, 6, 7, 8, 9]
cumsum: [1, 3, 6, 10, 15, 21, 28, 36, 45]
``````

The same technique can be applied to find the cum product, mean, etc.

``````p = 1
cumprod = [p := p * n for n in nums]
print(f'cumprod: {cumprod}')

s = 0
c = 0
cumavg = [(s := s + n) / (c := c + 1) for n in nums]
print(f'cumavg: {cumavg}')
``````

results in

``````cumprod: [1, 2, 6, 24, 120, 720, 5040, 40320, 362880]
cumavg: [1.0, 1.5, 2.0, 2.5, 3.0, 3.5, 4.0, 4.5, 5.0]
``````

If You want a pythonic way without numpy working in 2.7 this would be my way of doing it

``````l = [1,2,3,4]
_d={-1:0}
cumsum=[_d.setdefault(idx, _d[idx-1]+item) for idx,item in enumerate(l)]
``````

now let's try it and test it against all other implementations

``````import timeit, sys
L=list(range(10000))
if sys.version_info >= (3, 0):
reduce = functools.reduce
xrange = range

def sum1(l):
cumsum=[]
total = 0
for v in l:
total += v
cumsum.append(total)
return cumsum

def sum2(l):
import numpy as np
return list(np.cumsum(l))

def sum3(l):
return [sum(l[:i+1]) for i in xrange(len(l))]

def sum4(l):
return reduce(lambda c, x: c + [c[-1] + x], l, [0])[1:]

def this_implementation(l):
_d={-1:0}
return [_d.setdefault(idx, _d[idx-1]+item) for idx,item in enumerate(l)]

# sanity check
sum1(L)==sum2(L)==sum3(L)==sum4(L)==this_implementation(L)
>>> True

# PERFORMANCE TEST
timeit.timeit('sum1(L)','from __main__ import sum1,sum2,sum3,sum4,this_implementation,L', number=100)/100.
>>> 0.001018061637878418

timeit.timeit('sum2(L)','from __main__ import sum1,sum2,sum3,sum4,this_implementation,L', number=100)/100.
>>> 0.000829620361328125

timeit.timeit('sum3(L)','from __main__ import sum1,sum2,sum3,sum4,this_implementation,L', number=100)/100.
>>> 0.4606760001182556

timeit.timeit('sum4(L)','from __main__ import sum1,sum2,sum3,sum4,this_implementation,L', number=100)/100.
>>> 0.18932826995849608

timeit.timeit('this_implementation(L)','from __main__ import sum1,sum2,sum3,sum4,this_implementation,L', number=100)/100.
>>> 0.002348129749298096
``````

There could be many answers for this depending on the length of the list and the performance. One very simple way which I can think without thinking of the performance is this:

``````a = [1, 2, 3, 4]
a = [sum(a[0:x]) for x in range(1, len(a)+1)]
print(a)
``````

`[1, 3, 6, 10]`

This is by using list comprehension and this may work fairly well it is just that here I am adding over the subarray many times, you could possibly improvise on this and make it simple!

• This approach is `O(n²)`, so it only makes sense to use it for tiny lists. Sep 11, 2021 at 18:40

First, you want a running list of subsequences:

``````subseqs = (seq[:i] for i in range(1, len(seq)+1))
``````

Then you just call `sum` on each subsequence:

``````sums = [sum(subseq) for subseq in subseqs]
``````

(This isn't the most efficient way to do it, because you're adding all of the prefixes repeatedly. But that probably won't matter for most use cases, and it's easier to understand if you don't have to think of the running totals.)

If you're using Python 3.2 or newer, you can use `itertools.accumulate` to do it for you:

``````sums = itertools.accumulate(seq)
``````

And if you're using 3.1 or earlier, you can just copy the "equivalent to" source straight out of the docs (except for changing `next(it)` to `it.next()` for 2.5 and earlier).

• This runs in quadratic time (maybe that doesn't matter for the OP, but worth mentioning). Apr 8, 2013 at 21:24
• First, when N=3, who cares about quadratic time? And I don't think it's overcomplicated. It's two very simple steps, each transforming one iterator into another, directly translating the English-language description. (The fact that he's using an uncommon way of defining series, where the 0-length prefix isn't counted, does make it a bit more complicated… but that's inherent in the problem, and I thought it was better to put that in the `range` than to hack around it by doing `[1:]` at the end, or to ignore it.) Apr 8, 2013 at 21:26
• Presumably the OP's actual problem isn't to get the partial sums of `[4,6,12]` since, as he wrote in the question, he already knows what that is! Apr 8, 2013 at 21:27
• @ChrisTaylor: He explicitly said that he already knows how to write this, but wants "an easier way to write it". Apr 8, 2013 at 21:35
``````values = [4, 6, 12]
total  = 0
sums   = []

for v in values:
total = total + v
sums.append(total)

print 'Values: ', values
print 'Sums:   ', sums
``````

Running this code gives

``````Values: [4, 6, 12]
Sums:   [4, 10, 22]
``````

Try this:

``````result = []
acc = 0
for i in time_interval:
acc += i
result.append(acc)
``````
``````l = [1,-1,3]
cum_list = l

def sum_list(input_list):
index = 1
for i in input_list[1:]:
cum_list[index] = i + input_list[index-1]
index = index + 1
return cum_list

print(sum_list(l))
``````

In Python3, To find the cumulative sum of a list where the `i`th element is the sum of the first i+1 elements from the original list, you may do:

``````a = [4 , 6 , 12]
b = []
for i in range(0,len(a)):
b.append(sum(a[:i+1]))
print(b)
``````

OR you may use list comprehension:

``````b = [sum(a[:x+1]) for x in range(0,len(a))]
``````

Output

``````[4,10,22]
``````
• This looks right but can drop a link to the documentation, without that I cannot upvote. Jun 16, 2020 at 18:03
``````lst = [4, 6, 12]

[sum(lst[:i+1]) for i in xrange(len(lst))]
``````

If you are looking for a more efficient solution (bigger lists?) a generator could be a good call (or just use `numpy` if you really care about performance).

``````def gen(lst):
acu = 0
for num in lst:
yield num + acu
acu += num

print list(gen([4, 6, 12]))
``````
``````In [42]: a = [4, 6, 12]

In [43]: [sum(a[:i+1]) for i in xrange(len(a))]
Out[43]: [4, 10, 22]
``````

This is slighlty faster than the generator method above by @Ashwini for small lists

``````In [48]: %timeit list(accumu([4,6,12]))
100000 loops, best of 3: 2.63 us per loop

In [49]: %timeit [sum(a[:i+1]) for i in xrange(len(a))]
100000 loops, best of 3: 2.46 us per loop
``````

For larger lists, the generator is the way to go for sure. . .

``````In [50]: a = range(1000)

In [51]: %timeit [sum(a[:i+1]) for i in xrange(len(a))]
100 loops, best of 3: 6.04 ms per loop

In [52]: %timeit list(accumu(a))
10000 loops, best of 3: 162 us per loop
``````
• You're timing for just 3 item list, try for 10^4 items. Apr 8, 2013 at 21:32
• True, for larger lists the generator is far faster! Apr 8, 2013 at 21:33

Somewhat hacky, but seems to work:

``````def cumulative_sum(l):
y = [0]
def inc(n):
y[0] += n
return y[0]
return [inc(x) for x in l]
``````

I did think that the inner function would be able to modify the `y` declared in the outer lexical scope, but that didn't work, so we play some nasty hacks with structure modification instead. It is probably more elegant to use a generator.

Without having to use Numpy, you can loop directly over the array and accumulate the sum along the way. For example:

``````a=range(10)
i=1
while((i>0) & (i<10)):
a[i]=a[i-1]+a[i]
i=i+1
print a
``````

Results in:

``````[0, 1, 3, 6, 10, 15, 21, 28, 36, 45]
``````

A pure python oneliner for cumulative sum:

``````cumsum = lambda X: X[:1] + cumsum([X[0]+X[1]] + X[2:]) if X[1:] else X
``````

This is a recursive version inspired by recursive cumulative sums. Some explanations:

1. The first term `X[:1]` is a list containing the previous element and is almost the same as `[X[0]]` (which would complain for empty lists).
2. The recursive `cumsum` call in the second term processes the current element `[1]` and remaining list whose length will be reduced by one.
3. `if X[1:]` is shorter for `if len(X)>1`.

Test:

``````cumsum([4,6,12])
#[4, 10, 22]

cumsum([])
#[]
``````

And simular for cumulative product:

``````cumprod = lambda X: X[:1] + cumprod([X[0]*X[1]] + X[2:]) if X[1:] else X
``````

Test:

``````cumprod([4,6,12])
#[4, 24, 288]
``````

Here's another fun solution. This takes advantage of the `locals()` dict of a comprehension, i.e. local variables generated inside the list comprehension scope:

``````>>> [locals().setdefault(i, (elem + locals().get(i-1, 0))) for i, elem
in enumerate(time_interval)]
[4, 10, 22]
``````

Here's what the `locals()` looks for each iteration:

``````>>> [[locals().setdefault(i, (elem + locals().get(i-1, 0))), locals().copy()][1]
for i, elem in enumerate(time_interval)]
[{'.0': <enumerate at 0x21f21f7fc80>, 'i': 0, 'elem': 4, 0: 4},
{'.0': <enumerate at 0x21f21f7fc80>, 'i': 1, 'elem': 6, 0: 4, 1: 10},
{'.0': <enumerate at 0x21f21f7fc80>, 'i': 2, 'elem': 12, 0: 4, 1: 10, 2: 22}]
``````

Performance is not terrible for small lists:

``````>>> %timeit list(accumulate([4, 6, 12]))
387 ns ± 7.53 ns per loop (mean ± std. dev. of 7 runs, 1000000 loops each)

>>> %timeit np.cumsum([4, 6, 12])
5.31 µs ± 67.8 ns per loop (mean ± std. dev. of 7 runs, 100000 loops each)

>>> %timeit [locals().setdefault(i, (e + locals().get(i-1,0))) for i,e in enumerate(time_interval)]
1.57 µs ± 12 ns per loop (mean ± std. dev. of 7 runs, 1000000 loops each)
``````

And obviously falls flat for larger lists.

``````>>> l = list(range(1_000_000))
>>> %timeit list(accumulate(l))
95.1 ms ± 5.22 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)

>>> %timeit np.cumsum(l)
79.3 ms ± 1.07 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)

>>> %timeit np.cumsum(l).tolist()
120 ms ± 1.23 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)

>>> %timeit [locals().setdefault(i, (e + locals().get(i-1, 0))) for i, e in enumerate(l)]
660 ms ± 5.14 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
``````

Even though the method is ugly and not practical, it sure is fun.

I think the below code is the easiest:

``````a=[1,1,2,1,2]
b=[a[0]]+[sum(a[0:i]) for i in range(2,len(a)+1)]
``````
``````    def cumulative_sum(list):
l = []
for i in range(len(list)):
new_l = sum(list[:i+1])
l.append(new_l)
return l

time_interval = [4, 6, 12]
print(cumulative_sum(time_interval)
``````

Maybe a more beginner-friendly solution.

So you need to make a list of cumulative sums. You can do it by using for loop and .append() method

``````time_interval = [4, 6, 12]

cumulative_sum = []
new_sum = 0
for i in time_interval:
new_sum += i
cumulative_sum.append(new_sum)
print(cumulative_sum)
``````

or, using `numpy` module

``````import numpy

time_interval = [4, 6, 12]
c_sum = numpy.cumsum(time_interval)
print(c_sum.tolist())
``````

``````def wrand(vtlg):