# How do I subtract one list from another?

I want to take the difference between lists x and y:

>>> x = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
>>> y = [1, 3, 5, 7, 9]
>>> x - y
# should return [0, 2, 4, 6, 8]
• What should [2, 2] - [2] return? []? [2]? Jan 24, 2017 at 20:08
• What should [2, 1, 2, 3, 2, 4, 2] - [2, 3, 2] return, and why? Should it find the 232 in the middle and return 2142? or should it find the first each time and return 1242? Or something else? What I'm saying is that these are not obvious answers and depend on need. Jul 5, 2017 at 15:07

Use a list comprehension to compute the difference while maintaining the original order from x:

[item for item in x if item not in y]

If you don't need list properties (e.g. ordering), use a set difference, as the other answers suggest:

list(set(x) - set(y))

To allow x - y infix syntax, override __sub__ on a class inheriting from list:

class MyList(list):
def __init__(self, *args):
super(MyList, self).__init__(args)

def __sub__(self, other):
return self.__class__(*[item for item in self if item not in other])

Usage:

x = MyList(1, 2, 3, 4)
y = MyList(2, 5, 2)
z = x - y
• If you do [1,1,2,2] - [1,2] you will get empty list. [1,1,2,2] - [2] gives [1,1] So it is not really list substraction, it is more like "List from List X without elements from set Y". Feb 6, 2016 at 10:25
• The list comprehension method is way slower (in my example) than the set difference method. Feb 26, 2019 at 10:22
• @BarnabasSzabolcs: That won't save a thing, because it will convert y to a set before every check (which is similar cost to original work). You'd need to either do yset = set(y) outside the listcomp, then test if item not in yset, or as an egregious hack, do [item for yset in [set(y)] for item in x if item not in yset] which abuses nested listcomps to cache the yset as a one-liner. A slightly less ugly one-liner solution that performs adequately would be to use list(itertools.filterfalse(set(y).__contains__, x)) because the argument to filterfalse is only constructed once. Sep 5, 2019 at 22:03
• A solution that is O(n) fast and preserves order: ys_set = set(ys); result = [x for x in xs if x not in ys_set]. Feb 5, 2023 at 22:37
>>> z = list(set(x) - set(y))
>>> z
[0, 8, 2, 4, 6]

Or you might just have x and y be sets so you don't have to do any conversions.

• this will lose any ordering. That may or may not matter depending on context. Aug 7, 2010 at 0:19
• This will also loose any possible duplicates that may need/want maintaining.
– Opal
Jun 24, 2011 at 5:31
• This is way faster in cases where the lists being compared are large Oct 6, 2018 at 2:57

if duplicate and ordering items are problem :

[i for i in a if not i in b or b.remove(i)]

a = [1,2,3,3,3,3,4]
b = [1,3]
result: [2, 3, 3, 3, 4]
• This works, though it's O(m * n) runtime (and I cringe whenever a listcomp includes side-effects); you can improve on it using collections.Counter to get O(m + n) runtime. Sep 6, 2019 at 18:50
• @anushka Rather than [item for item in a if not item in b] (which works more like set subtraction), this has ... if not item in b or b.remove(item). b.remove(item) returns false if item is not in b and removes item from b otherwise. This prevents items in the second list (a - b, in this case) from being subtracted more than once for each occurrence. This prevents de-duping, which happens if you follow some of the other answers. It's not super-efficient (definitely follow @ShaworRangers suggestion for efficiency), but I think this is probably the most-correct answer. Jul 1, 2022 at 0:38

That is a "set subtraction" operation. Use the set data structure for that.

In Python 2.7:

x = {1,2,3,4,5,6,7,8,9,0}
y = {1,3,5,7,9}
print x - y

Output:

>>> print x - y
set([0, 8, 2, 4, 6])
• list(set([1,2,3,4,5]) - set([1,2,3])) = [4, 5] so that's lists each to set first, then subtract (or one-way diff) and back to list. Jun 5, 2017 at 8:22
• Not good if you like to maintain original item order of the x set. Aug 26, 2017 at 17:16

For many use cases, the answer you want is:

ys = set(y)
[item for item in x if item not in ys]

aaronasterling's version does len(y) item comparisons for each element in x, so it takes quadratic time. quantumSoup's version uses sets, so it does a single constant-time set lookup for each element in x—but, because it converts both x and y into sets, it loses the order of your elements.

By converting only y into a set, and iterating x in order, you get the best of both worlds—linear time, and order preservation.*

However, this still has a problem from quantumSoup's version: It requires your elements to be hashable. That's pretty much built into the nature of sets.** If you're trying to, e.g., subtract a list of dicts from another list of dicts, but the list to subtract is large, what do you do?

If you can decorate your values in some way that they're hashable, that solves the problem. For example, with a flat dictionary whose values are themselves hashable:

ys = {tuple(item.items()) for item in y}
[item for item in x if tuple(item.items()) not in ys]

If your types are a bit more complicated (e.g., often you're dealing with JSON-compatible values, which are hashable, or lists or dicts whose values are recursively the same type), you can still use this solution. But some types just can't be converted into anything hashable.

If your items aren't, and can't be made, hashable, but they are comparable, you can at least get log-linear time (O(N*log M), which is a lot better than the O(N*M) time of the list solution, but not as good as the O(N+M) time of the set solution) by sorting and using bisect:

ys = sorted(y)
def bisect_contains(seq, item):
index = bisect.bisect(seq, item)
return index < len(seq) and seq[index] == item
[item for item in x if bisect_contains(ys, item)]

If your items are neither hashable nor comparable, then you're stuck with the quadratic solution.

* Note that you could also do this by using a pair of OrderedSet objects, for which you can find recipes and third-party modules. But I think this is simpler.

** The reason set lookups are constant time is that all it has to do is hash the value and see if there's an entry for that hash. If it can't hash the value, this won't work.

If the lists allow duplicate elements, you can use Counter from collections:

from collections import Counter
result = list((Counter(x)-Counter(y)).elements())

If you need to preserve the order of elements from x:

result = [ v for c in [Counter(y)] for v in x if not c[v] or c.subtract([v]) ]
• This is good, though it does lose ordering; fixing that is a bit more complicated. Sep 6, 2019 at 18:47
• Don't mind me, I'm just going to shudder at listcomps with caching and side-effects (although I suppose the combination of the two removes the externally visible side-effects?). :-) Sep 6, 2019 at 19:41
• Also, this code won't work as written; Counter.subtract doesn't remove zero valued elements (- and -= do, but not subtract), so you'd never stop removing elements. You'd want to replace not v in c with not c[v] (which returns zero for non-existent elements, so you can safely test the return for "zeroiness" via not). Sep 6, 2019 at 19:44
• .elements() is unncessary. list((Counter(x) - Counter(y))) works for my case Sep 5, 2021 at 16:16
• As long as you don't have duplicate values in x, it does indeed, but in that case, using a set would probably be more efficient: [vx for ySet in [set(y)] for vx in x if vx not in ySet] (preserving the order of x), or list(set(x)-set(y)) if the order doesn't matter Sep 5, 2021 at 16:22

The other solutions have one of a few problems:

1. They don't preserve order, or
2. They don't remove a precise count of elements, e.g. for x = [1, 2, 2, 2] and y = [2, 2] they convert y to a set, and either remove all matching elements (leaving [1] only) or remove one of each unique element (leaving [1, 2, 2]), when the proper behavior would be to remove 2 twice, leaving [1, 2], or
3. They do O(m * n) work, where an optimal solution can do O(m + n) work

Alain was on the right track with Counter to solve #2 and #3, but that solution will lose ordering. The solution that preserves order (removing the first n copies of each value for n repetitions in the list of values to remove) is:

from collections import Counter

x = [1,2,3,4,3,2,1]
y = [1,2,2]
remaining = Counter(y)

out = []
for val in x:
if remaining[val]:
remaining[val] -= 1
else:
out.append(val)
# out is now [3, 4, 3, 1], having removed the first 1 and both 2s.

Try it online!

To make it remove the last copies of each element, just change the for loop to for val in reversed(x): and add out.reverse() immediately after exiting the for loop.

Constructing the Counter is O(n) in terms of y's length, iterating x is O(n) in terms of x's length, and Counter membership testing and mutation are O(1), while list.append is amortized O(1) (a given append can be O(n), but for many appends, the overall big-O averages O(1) since fewer and fewer of them require a reallocation), so the overall work done is O(m + n).

You can also test for to determine if there were any elements in y that were not removed from x by testing:

remaining = +remaining  # Removes all keys with zero counts from Counter
if remaining:
# remaining contained elements with non-zero counts
• Note: This does require the values to be hashable, but any solution that doesn't require hashable objects either isn't general purpose (e.g. can count ints into fixed length array) or has to do more than O(m + n) work (e.g. the next best big-O would be to make a sorted list of unique value/count pairs, changing O(1) dict lookups into O(log n) binary searches; you'd need unique values with their counts, not just sorted non-unique values, because otherwise you'd be paying O(n) costs to remove the elements from the sorted list). Sep 6, 2019 at 18:47
• I think this is the best answer so far, but for reference purposes I think it would be better if it was refactored into a function, as I presume typing out 5+ lines of code every time one wants to subtract two lists is a bit cumbersome. May 6, 2022 at 14:31

Looking up values in sets are faster than looking them up in lists:

[item for item in x if item not in set(y)]

I believe this will scale slightly better than:

[item for item in x if item not in y]

Both preserve the order of the lists.

• Will it cache set(y) and not convert y to a new set on each loop? Otherwise, you'd need abarnert's answer: ys = set(y); [i for i in x if i not in ys]. May 23, 2019 at 23:02
• Some rough testing suggests that if i not in set(y) takes 25% longer than if i not in y (where y is a list). Pre-converting the set takes 55% less time. Tested with pretty short x and y, but differences should get more pronounced with length, if anything. May 23, 2019 at 23:17
• @Jacktose: Yeah, this solution does more work, because it has to iterate and hash every element of y for every element of x; unless the equality comparison is really expensive relative to the hash computation, this will always lose to plain item not in y. Sep 6, 2019 at 18:28
• @ShadowRanger which makes sense. If set conversion was a reliably quicker way to do that check, you'd think the compiler would just always do the check that way. Sep 10, 2019 at 15:54

Let:

>>> xs = [1, 2, 3, 4, 3, 2, 1]
>>> ys = [1, 3, 3]

#### Keep each unique item only once   xs - ys == {2, 4}

Take the set difference:

>>> set(xs) - set(ys)
{2, 4}

#### Remove all occurrences   xs - ys == [2, 4, 2]

>>> [x for x in xs if x not in ys]
[2, 4, 2]

If ys is large, convert only1 ys into a set for better performance:

>>> ys_set = set(ys)
>>> [x for x in xs if x not in ys_set]
[2, 4, 2]

#### Only remove same number of occurrences   xs - ys == [2, 4, 2, 1]

from collections import Counter, defaultdict

def diff(xs, ys):
counter = Counter(ys)
for x in xs:
if counter[x] > 0:
counter[x] -= 1
continue
yield x

>>> list(diff(xs, ys))
[2, 4, 2, 1]

1 Converting xs to set and taking the set difference is unnecessary (and slower, as well as order-destroying) since we only need to iterate once over xs.

We can use set methods as well to find the difference between two list

x = [1, 2, 3, 4, 5, 6, 7, 8, 9, 0]
y = [1, 3, 5, 7, 9]
list(set(x).difference(y))
[0, 2, 4, 6, 8]

Try this.

def subtract_lists(a, b):
""" Subtracts two lists. Throws ValueError if b contains items not in a """
# Terminate if b is empty, otherwise remove b[0] from a and recurse
return a if len(b) == 0 else [a[:i] + subtract_lists(a[i+1:], b[1:])
for i in [a.index(b[0])]][0]

>>> x = [1,2,3,4,5,6,7,8,9,0]
>>> y = [1,3,5,7,9]
>>> subtract_lists(x,y)
[2, 4, 6, 8, 0]
>>> x = [1,2,3,4,5,6,7,8,9,0,9]
>>> subtract_lists(x,y)
[2, 4, 6, 8, 0, 9]     #9 is only deleted once
>>>

The answer provided by @aaronasterling looks good, however, it is not compatible with the default interface of list: x = MyList(1, 2, 3, 4) vs x = MyList([1, 2, 3, 4]). Thus, the below code can be used as a more python-list friendly:

class MyList(list):
def __init__(self, *args):
super(MyList, self).__init__(*args)

def __sub__(self, other):
return self.__class__([item for item in self if item not in other])

Example:

x = MyList([1, 2, 3, 4])
y = MyList([2, 5, 2])
z = x - y
from collections import Counter

y = Counter(y)
x = Counter(x)

print(list(x-y))
list1 = ['a', 'c', 'a', 'b', 'k']
list2 = ['a', 'a', 'a', 'a', 'b', 'c', 'c', 'd', 'e', 'f']
for e in list1:
try:
list2.remove(e)
except ValueError:
print(f'{e} not in list')
list2
# ['a', 'a', 'c', 'd', 'e', 'f']

This will change list2. if you want to protect list2 just copy it and use the copy of list2 in this code.

This example subtracts two lists:

# List of pairs of points
list = []
list.append([(602, 336), (624, 365)])
list.append([(635, 336), (654, 365)])
list.append([(642, 342), (648, 358)])
list.append([(644, 344), (646, 356)])
list.append([(653, 337), (671, 365)])
list.append([(728, 13), (739, 32)])
list.append([(756, 59), (767, 79)])

itens_to_remove = []
itens_to_remove.append([(642, 342), (648, 358)])
itens_to_remove.append([(644, 344), (646, 356)])

print("Initial List Size: ", len(list))

for a in itens_to_remove:
for b in list:
if a == b :
list.remove(b)

print("Final List Size: ", len(list))
• Avoid this, it's O(N^2) Mar 10, 2017 at 5:38
def listsubtraction(parent,child):