# Check if all elements in a list are equal

I need a function which takes in a `list` and outputs `True` if all elements in the input list evaluate as equal to each other using the standard equality operator and `False` otherwise.

I feel it would be best to iterate through the list comparing adjacent elements and then `AND` all the resulting Boolean values. But I'm not sure what's the most Pythonic way to do that.

• Equal as in `a == b` or identical as in `a is b`? Commented Oct 2, 2010 at 7:35
• Should the solution handle empty lists? If so, what should be returned?
– Doug
Commented Oct 2, 2010 at 7:43
• Equal as in a == b. Should handle empty list, and return True.
– max
Commented Oct 2, 2010 at 8:21
• Although I know it's slower than some of the other recommendations, I'm surprised `functools.reduce(operator.eq, a)` hasn't been suggested. Commented Apr 5, 2020 at 21:55
• @ user2846495 `functools.reduce(operator.eq, a)` would not work. for example with the list `[True, False, False]`, it would return `((True == False) == False)` which is `True`. Whereas the function should return False (because the elements are not all equal) Commented Apr 19, 2021 at 15:40

## 33 Answers

``````from itertools import groupby

def all_equal(iterable):
g = groupby(iterable)
return next(g, True) and not next(g, False)
``````

or without `groupby`:

``````def all_equal(iterator):
iterator = iter(iterator)
try:
first = next(iterator)
except StopIteration:
return True
return all(first == x for x in iterator)
``````

There are a number of alternative one-liners you might consider:

1. Converting the input to a set and checking that it only has one or zero (in case the input is empty) items

``````def all_equal2(iterator):
return len(set(iterator)) <= 1
``````
2. Comparing against the input list without the first item

``````def all_equal3(lst):
return lst[:-1] == lst[1:]
``````
3. Counting how many times the first item appears in the list

``````def all_equal_ivo(lst):
return not lst or lst.count(lst[0]) == len(lst)
``````
4. Comparing against a list of the first element repeated

``````def all_equal_6502(lst):
return not lst or [lst[0]]*len(lst) == lst
``````

But they have some downsides, namely:

1. `all_equal` and `all_equal2` can use any iterators, but the others must take a sequence input, typically concrete containers like a list or tuple.
2. `all_equal` and `all_equal3` stop as soon as a difference is found (what is called "short circuit"), whereas all the alternatives require iterating over the entire list, even if you can tell that the answer is `False` just by looking at the first two elements.
3. In `all_equal2` the content must be hashable. A list of lists will raise a `TypeError` for example.
4. `all_equal2` (in the worst case) and `all_equal_6502` create a copy of the list, meaning you need to use double the memory.

On Python 3.9, using `perfplot`, we get these timings (lower `Runtime [s]` is better):

• Don't forget memory usage analysis for very large arrays, a native solution which optimizes away calls to `obj.__eq__` when `lhs is rhs`, and out-of-order optimizations to allow short circuiting sorted lists more quickly. Commented Oct 2, 2010 at 8:31
• In case the intuition on checkEqual3 wasn't immediately obvious to anyone else: all items are the same if `first == second and second == third and ...` Commented May 19, 2020 at 17:16
• This is brilliantly fast. Clever approach too. Helpful suggestion for those implementing with `pytest`, you should return the result before asserting True/False. (Wrap this function in another.) Commented Dec 20, 2020 at 17:43
• @Boris: What is the code for these charts? Commented Jan 27, 2021 at 5:51
• @ChaimG if you click on "Edit", the code is hidden in a comment in the text of the answer.
– user3064538
Commented Jan 27, 2021 at 12:10

A solution faster than using set() that works on sequences (not iterables) is to simply count the first element. This assumes the list is non-empty (but that's trivial to check, and decide yourself what the outcome should be on an empty list)

``````x.count(x[0]) == len(x)
``````

some simple benchmarks:

``````>>> timeit.timeit('len(set(s1))<=1', 's1=[1]*5000', number=10000)
1.4383411407470703
>>> timeit.timeit('len(set(s1))<=1', 's1=[1]*4999+[2]', number=10000)
1.4765670299530029
>>> timeit.timeit('s1.count(s1[0])==len(s1)', 's1=[1]*5000', number=10000)
0.26274609565734863
>>> timeit.timeit('s1.count(s1[0])==len(s1)', 's1=[1]*4999+[2]', number=10000)
0.25654196739196777
``````
• OMG, this is 6 times faster than the set solution! (280 million elements/sec vs 45 million elements/sec on my laptop). Why??? And is there any way to modify it so that it short circuits (I guess not...)
– max
Commented Oct 2, 2010 at 9:18
• I guess list.count has a highly optimized C implementation, and the length of the list is stored internally, so len() is cheap as well. There's not a way to short-circuit count() since you will need to really check all elements to get the correct count. Commented Oct 2, 2010 at 10:01
• Can I change it to: `x.count(next(x)) == len(x)` so that it works for any container x? Ahh.. nm, just saw that .count is only available for sequences.. Why isn't it implemented for other builtin containers? Is counting inside a dictionary inherently less meaningful than inside a list?
– max
Commented Oct 5, 2010 at 5:09
• An iterator may not have a length. E.g. it can be infinite or just dynamically generated. You can only find its length by converting it to a list which takes away most of the iterators advantages Commented Oct 5, 2010 at 5:51
• Sorry, what I meant was why `count` isn't implemented for iterables, not why `len` isn't available for iterators. The answer is probably that it's just an oversight. But it's irrelavant for us because default `.count()` for sequences is very slow (pure python). The reason your solution is so fast is that it relies on the C-implemented `count` provided by `list`. So I suppose whichever iterable happens to implement `count` method in C will benefit from your approach.
– max
Commented Mar 12, 2016 at 3:36

[edit: This answer addresses the currently top-voted `itertools.groupby` (which is a good answer) answer later on.]

Without rewriting the program, the most asymptotically performant and most readable way is as follows:

``````all(x==myList[0] for x in myList)
``````

(Yes, this even works with the empty list! This is because this is one of the few cases where python has lazy semantics.)

This will fail at the earliest possible time, so it is asymptotically optimal (expected time is approximately O(#uniques) rather than O(N), but worst-case time still O(N)). This is assuming you have not seen the data before...

(If you care about performance but not that much about performance, you can just do the usual standard optimizations first, like hoisting the `myList[0]` constant out of the loop and adding clunky logic for the edge case, though this is something the python compiler might eventually learn how to do and thus one should not do it unless absolutely necessary, as it destroys readability for minimal gain.)

If you care slightly more about performance, this is twice as fast as above but a bit more verbose:

``````def allEqual(iterable):
iterator = iter(iterable)

try:
firstItem = next(iterator)
except StopIteration:
return True

for x in iterator:
if x!=firstItem:
return False
return True
``````

If you care even more about performance (but not enough to rewrite your program), use the currently top-voted `itertools.groupby` answer, which is twice as fast as `allEqual` because it is probably optimized C code. (According to the docs, it should (similar to this answer) not have any memory overhead because the lazy generator is never evaluated into a list... which one might be worried about, but the pseudocode shows that the grouped 'lists' are actually lazy generators.)

If you care even more about performance read on...

sidenotes regarding performance, because the other answers are talking about it for some unknown reason:

... if you have seen the data before and are likely using a collection data structure of some sort, and you really care about performance, you can get `.isAllEqual()` for free O(1) by augmenting your structure with a `Counter` that is updated with every insert/delete/etc. operation and just checking if it's of the form `{something:someCount}` i.e. `len(counter.keys())==1`; alternatively you can keep a Counter on the side in a separate variable. This is provably better than anything else up to constant factor. Perhaps you can also use python's FFI with `ctypes` with your chosen method, and perhaps with a heuristic (like if it's a sequence with getitem, then checking first element, last element, then elements in-order).

Of course, there's something to be said for readability.

• max: Likely because I did not bother to perform the optimization `first=myList[0]` `all(x==first for x in myList)`, perhaps Commented Nov 17, 2015 at 12:48
• I should of course clarify that the optimization `first=myList[0]` will throw an `IndexError` on an empty list, so commenters who were talking about that optimization I mentioned will have to deal with the edge-case of an empty list. However the original is fine (`x==myList[0]` is fine within the `all` because it is never evaluated if the list is empty). Commented Jan 13, 2016 at 10:45
• This is clearly the right way to to it. If you want speed in every case, use something like numpy. Commented May 6, 2016 at 16:14
• @KellyBundy Please stop replying to every comment I make on these posts. You clearly don't have enough experience with Python to understand the points being made so I don't know why you are insistent on replying to every comment I make. It is fragile for several reasons. Firstly it is not obvious what it is doing, it is not readable. Secondly it takes 10 lines to achieve what can be achieved in a single line. Like many of the other answers posted here it's just not a good solution in any way. The only purpose this serves is to obscure the good answers. Commented Feb 20 at 9:46
• @FreelanceConsultant It's absolutely not "none". You have to implement the functionality somehow. And comparing all values to the first is the most natural choice. It's what you'd do in real life, too. If I said I'll show you a sequence of colors and you shall tell me if they're all equal, and the first color I show you is red, you'd set your mind to "red" and just check whether all remaining colors are also red, wouldn't you? Also, index 0 is guaranteed to exist when you want to do a comparison. "What this code does is instead ask the question"? Nonsense. It answers a question. Commented Feb 26 at 12:59

Convert your input into a `set`:

``````len(set(the_list)) <= 1
``````

Using `set` removes all duplicate elements. `<= 1` is so that it correctly returns `True` when the input is empty.

This requires that all the elements in your input are hashable. You'll get a `TypeError` if you pass in a list of lists for example.

• Why should an empty list be `True` instead of `False`. It will depend on what the client wants. In my particular case, yes, I also happen to want `True` for an empty input. But this is specific to my current problem. Commented Feb 17 at 22:33
• @FreelanceConsultant Because that's the standard. See Vacuous truth and note that for example Python's `all([])` is also `True`, for that reason. And if someone does want to deviate from the standard, they can simply use `== 1`. Commented Feb 18 at 1:51
• @KellyBundy I'm not talking about that. I am making the point that since you don't know what the calling client wants you cannot know in advance which is 'correct' from the client point of view Commented Feb 18 at 17:12

You can convert the list to a set. A set cannot have duplicates. So if all the elements in the original list are identical, the set will have just one element.

``````if len(set(input_list)) == 1:
# input_list has all identical elements.
``````
• this is nice but it doesn't short circuit and you have to calculate the length of the resulting list. Commented Oct 2, 2010 at 7:44
• @AaronMcSmooth: Still a noob in py. Don't even know what a short circut in py means :) Commented Oct 2, 2010 at 7:55
• @codaddict. It means that even if the first two elements are distinct, it will still complete the entire search. it also uses O(k) extra space where k is the number of distinct elements in the list. Commented Oct 2, 2010 at 7:58
• @max. because building the set happens in C and you have a bad implementation. You should at least do it in a generator expression. See KennyTM's answer for how to do it correctly without using a set. Commented Oct 2, 2010 at 8:20
• This returns `False` if your list is empty, when it should return `True`. It also requires all your elements to be hashable.
– user3064538
Commented Nov 1, 2020 at 17:23

For what it's worth, this came up on the python-ideas mailing list recently. It turns out that there is an itertools recipe for doing this already:1

``````def all_equal(iterable):
"Returns True if all the elements are equal to each other"
g = groupby(iterable)
return next(g, True) and not next(g, False)
``````

Supposedly it performs very nicely and has a few nice properties.

1. Short-circuits: It will stop consuming items from the iterable as soon as it finds the first non-equal item.
2. Doesn't require items to be hashable.
3. It is lazy and only requires O(1) additional memory to do the check.

1In other words, I can't take the credit for coming up with the solution -- nor can I take credit for even finding it.

• `return next(g, f := next(g, g)) == f` (from py3.8 of course) Commented Apr 26, 2020 at 10:41
• To make this work with `pd.NA`, just add an exception handler. Commented Jan 25, 2023 at 17:56
• This recipe is slightly flawed and wasteful in that `next(g, True)` always returns `True` and consequently the expression doesn't short-circuit immediately when the given iterable is empty. It can be made more efficient with `return not (next(g, False) and next(g, False))` instead. Commented Feb 20 at 3:30

This is a simple way of doing it:

``````result = mylist and all(mylist[0] == elem for elem in mylist)
``````

This is slightly more complicated, it incurs function call overhead, but the semantics are more clearly spelled out:

``````def all_identical(seq):
if not seq:
# empty list is False.
return False
first = seq[0]
return all(first == elem for elem in seq)
``````
• You can avoid a redundant comparison here by using `for elem in mylist[1:]`. Doubt it improves speed much though since I guess `elem[0] is elem[0]` so the interpreter can probably do that comparison very quickly. Commented Jan 5, 2017 at 15:58
• Shouldn't an empty list be `True`? Why manually invert the True/False value, when this is answering a different question to a different problem. Commented Feb 17 at 22:27

This is another option, faster than `len(set(x))==1` for long lists (uses short circuit)

``````def constantList(x):
return x[:1]*len(x) == x
``````
• It is 3 times slower than the set solution on my computer, ignoring short circuit. So if the unequal element is found on average in the first third of the list, it's faster on average.
– max
Commented Oct 2, 2010 at 9:21
• And uses double the memory? Commented Feb 17 at 22:26
• @FreelanceConsultant: not really... temporarily allocates `O(n)` memory but the allocated list will just be of `n` pointers to the same element `x[0]`. Note that even say a floating point number takes a huge amount of memory in Python (compared to say C++ is about 3x) and list elements are 8 bytes (they're just pointers). The reason for the speed is that both loops (the one initializing lists elements and the one doing the comparison) are running in C and not as python code (and python code is really, really, REALLY slow compared to C).
– 6502
Commented Feb 18 at 6:47
• So it uses double the memory Commented Feb 18 at 17:02
• @FreelanceConsultant: no... it uses 8*n bytes of memory that is normally a lot less of what a list wtith `n` elements takes (it's just the list overhead, without the elements). If you still can't understand it, I'm sorry but it's probably a topic too complex for you. The `count` approach is faster if the answer is true as the loop is also in C but there's no need for the memory allocation, however is not short circuiting. As usual YMMV.
– 6502
Commented Feb 18 at 21:12

Check if all elements equal to the first.

`np.allclose(array, array[0])`

• Needs third party module. Commented Feb 27, 2019 at 21:39
• Also only works for a few specific types, and it's slow because of the transform of data to `numpy` array Commented Feb 17 at 22:25

## Best Answer

There was a nice Twitter thread on the various ways to implement an all_equal() function.

Given a list input, the best submission was:

`````` t.count(t[0]) == len(t)
``````

## Other Approaches

Here is are the results from the thread:

1. Have groupby() compare adjacent entries. This has an early-out for a mismatch, does not use extra memory, and it runs at C speed.

``````g = itertools.groupby(s)
next(g, True) and not next(g, False)
``````
2. Compare two slices offset from one another by one position. This uses extra memory but runs at C speed.

``````s[1:] == s[:-1]
``````
3. Iterator version of slice comparison. It runs at C speed and does not use extra memory; however, the eq calls are expensive.

``````all(map(operator.eq, s, itertools.islice(s, 1, None)))
``````
4. Compare the lowest and highest values. This runs at C speed, doesn't use extra memory, but does cost two inequality tests per datum.

``````min(s) == max(s)  # s must be non-empty
``````
5. Build a set. This runs at C speed and uses little extra memory but requires hashability and does not have an early-out.

``````len(set(t))==1.
``````
6. At great cost, this handles NaNs and other objects with exotic equality relations.

``````all(itertools.starmap(eq, itertools.product(s, repeat=2)))
``````
7. Pull out the first element and compare all the others to it, stopping at the first mismatch. Only disadvantage is that this doesn't run at C speed.

`````` it = iter(s)
a = next(it, None)
return all(a == b for b in it)
``````
8. Just count the first element. This is fast, simple, elegant. It runs at C speed, requires no additional memory, uses only equality tests, and makes only a single pass over the data.

``````  t.count(t[0]) == len(t)
``````
• About 12x faster alternative for the `product` check: `min(map(s.count, s)) == len(s)` Commented May 10, 2022 at 3:03
• The only good answer here is `3` which still has problems because it depends on the arbitrary index manipulation Commented Feb 17 at 22:25

Doubt this is the "most Pythonic", but something like:

``````>>> falseList = [1,2,3,4]
>>> trueList = [1, 1, 1]
>>>
>>> def testList(list):
...   for item in list[1:]:
...     if item != list[0]:
...       return False
...   return True
...
>>> testList(falseList)
False
>>> testList(trueList)
True
``````

would do the trick.

• Your `for` loop can be made more Pythonic into `if any(item != list[0] for item in list[1:]): return False`, with exactly the same semantics. Commented Aug 18, 2016 at 20:59
• This really isn't great because it relies on hoisting the arbitrary value `list[0]` out of the enclosing scope Commented Feb 17 at 22:23
``````>>> a = [1, 2, 3, 4, 5, 6]
>>> z = [(a[x], a[x+1]) for x in range(0, len(a)-1)]
>>> z
[(1, 2), (2, 3), (3, 4), (4, 5), (5, 6)]
# Replacing it with the test
>>> z = [(a[x] == a[x+1]) for x in range(0, len(a)-1)]
>>> z
[False, False, False, False, False]
>>> if False in z : Print "All elements are not equal"
``````
• This has some issues: Hard to understand what is going on due to somewhat arbitrary index manipulation with `range`. Also not lazy evaluated. If you wrap the creation of the pairs in a function which `yields` and the apply `any()` in place of the final step, it would be a lot better Commented Feb 17 at 22:17
``````def allTheSame(i):
j = itertools.groupby(i)
for k in j: break
for k in j: return False
return True
``````

Works in Python 2.4, which doesn't have "all".

• `for k in j: break` is equivalent to `next(j)`. You could also have done `def allTheSame(x): return len(list(itertools.groupby(x))<2)` if you did not care about efficiency. Commented Apr 23, 2012 at 17:06

I'd do:

``````all((x[i] == x[i+1] for i in range(0, len(x)-1)))
``````

as `all` stops searching the iterable as soon as it finds a `True` condition.

• You don't need the extra parentheses around the generator expression if it's the only argument. Commented Apr 23, 2012 at 17:02
• so does `all()`, why not use `all(x == seq[0] for x in seq)` ? looks more pythonic and should perform the same Commented Sep 4, 2017 at 7:36
• Reasonable, but relies on this awful arbitrary index manipulation Commented Feb 17 at 22:21
• @FreelanceConsultant Please don't break answers, at least adjust the text to the changed code. Commented Feb 18 at 2:50
• @FreelanceConsultant Because the code uses `all` but the text talks about `any`. Makes no sense. Btw, someone else might've had posted the `all` solution already and this answer might've intentionally showcased `any`, consciously avoiding duplicating the other answer. If that's the case (I'm not in the mood to research it), such a change is also bad for that reason. Commented Feb 18 at 17:19

Or use `diff` method of numpy:

``````import numpy as np
def allthesame(l):
return np.all(np.diff(l)==0)
``````

And to call:

``````print(allthesame([1,1,1]))
``````

Output:

``````True
``````
• I think `not np.any(np.diff(l))` could be a bit faster.
– GZ0
Commented Sep 5, 2019 at 22:39
• This depends on numpy and so will not work for the majority of types Commented Feb 17 at 22:14

Regarding using `reduce()` with `lambda`. Here is a working code that I personally think is way nicer than some of the other answers.

``````reduce(lambda x, y: (x[1]==y, y), [2, 2, 2], (True, 2))
``````

Returns a tuple where the first value is the boolean if all items are same or not.

• There is a small mistake in the code as written (try `[1, 2, 2]`): it doesn't take the previous boolean value into account. This can be fixed by replacing `x[1] == y` with `x[0] and x[1] == y`. Commented Mar 2, 2020 at 8:52
• It's not totally horrendous like some of these others - at least in principle, but I have no clue what the final part of the line is about, so I suspect it is wrong. Do you really need the arbitrary starting condition? `(True, 2)`. Also why does the initial condition have a `2` in it at all? Commented Feb 17 at 22:19

I ended up with this one-liner

``````from itertools import starmap, pairwise
all(starmap(eq, (pairwise(x)))
``````

More versions using `itertools.groupby` that I find clearer than the original (more about that below):

``````def all_equal(iterable):
g = groupby(iterable)
return not any(g) or not any(g)

def all_equal(iterable):
g = groupby(iterable)
next(g, None)
return not next(g, False)

def all_equal(iterable):
g = groupby(iterable)
return not next(g, False) or not next(g, False)
``````

Here's the original from the Itertools Recipes again:

``````def all_equal(iterable):
g = groupby(iterable)
return next(g, True) and not next(g, False)
``````

Note that the `next(g, True)` is always true (it's either a non-empty `tuple` or `True`). That means its value doesn't matter. It's executed purely for advancing the `groupby` iterator. But including it in the `return` expression leads the reader into thinking that its value gets used there. Since it doesn't, I find that misleading and unnecessarily complicated. My second version above treats the `next(g, True)` as what it's actually used for, as a statement whose value we don't care about.

My third version goes a different direction and does use the value of the first `next(g, False)`. If there isn't even a first group at all (i.e., if the given iterable is "empty"), then that solution returns the result right away and doesn't even check whether there's a second group.

My first solution is basically the same as my third, just using `any`. Both solutions read as "All elements are equal iff ... there is no first group or there is no second group."

Benchmark results (although speed is really not my point here, clarity is, and in practice if there are many equal values, most of the time might be spent by the `groupby` itself, reducing the impact of these differences here):

``````Python 3.10.4 on my Windows laptop:

iterable = ()
914 ns   914 ns   916 ns  use_first_any
917 ns   925 ns   925 ns  use_first_next
1074 ns  1075 ns  1075 ns  next_as_statement
1081 ns  1083 ns  1084 ns  original

iterable = (1,)
1290 ns  1290 ns  1291 ns  next_as_statement
1303 ns  1307 ns  1307 ns  use_first_next
1306 ns  1307 ns  1309 ns  use_first_any
1318 ns  1319 ns  1320 ns  original

iterable = (1, 2)
1463 ns  1464 ns  1467 ns  use_first_any
1463 ns  1463 ns  1467 ns  next_as_statement
1477 ns  1479 ns  1481 ns  use_first_next
1487 ns  1489 ns  1492 ns  original
``````
``````Python 3.10.4 on a Debian Google Compute Engine instance:

iterable = ()
234 ns   234 ns   234 ns  use_first_any
234 ns   235 ns   235 ns  use_first_next
264 ns   264 ns   264 ns  next_as_statement
265 ns   265 ns   265 ns  original

iterable = (1,)
308 ns   308 ns   308 ns  next_as_statement
315 ns   315 ns   315 ns  original
316 ns   316 ns   317 ns  use_first_any
317 ns   317 ns   317 ns  use_first_next

iterable = (1, 2)
361 ns   361 ns   361 ns  next_as_statement
367 ns   367 ns   367 ns  original
384 ns   385 ns   385 ns  use_first_next
386 ns   387 ns   387 ns  use_first_any
``````

Benchmark code:

``````from timeit import timeit
from random import shuffle
from bisect import insort
from itertools import groupby

def original(iterable):
g = groupby(iterable)
return next(g, True) and not next(g, False)

def use_first_any(iterable):
g = groupby(iterable)
return not any(g) or not any(g)

def next_as_statement(iterable):
g = groupby(iterable)
next(g, None)
return not next(g, False)

def use_first_next(iterable):
g = groupby(iterable)
return not next(g, False) or not next(g, False)

funcs = [original, use_first_any, next_as_statement, use_first_next]

for iterable in (), (1,), (1, 2):
print(f'{iterable = }')
times = {func: [] for func in funcs}
for _ in range(1000):
shuffle(funcs)
for func in funcs:
number = 1000
t = timeit(lambda: func(iterable), number=number) / number
insort(times[func], t)
for func in sorted(funcs, key=times.get):
print(*('%4d ns ' % round(t * 1e9) for t in times[func][:3]), func.__name__)
print()
``````
• To make `all_equal` work with `pd.NA`, just add an exception handler. Commented Jan 25, 2023 at 17:59
• `groupby` is presumably going to do some form of sort first? In which case, why? Commented Feb 17 at 22:09
• @FreelanceConsultant No. Why presume that? Does its documentation somehow suggest that? Commented Feb 18 at 0:17
• @KellyBundy How else would groupby order unordered elements. I haven't looked into detail as to what algorithm is being used, but what I do know is any work being done by groupby is unnecessary Commented Feb 18 at 17:07
• @FreelanceConsultant It shouldn't surprise. The `groupby` iterator directly reads and compares the elements. In that other solution, `pairwise` reads the elements and creates 2-tuples of them, transmits those to `starmap`, which asks `eq` to compare them, which replies accordingly, and then `starmap` transmits the comparison results to `all`, which does its thing. That's a lot of overhead for each element. Should be expected to be slower. The "If you want speed, don't use Python" sentiment is inappropriate. You might want Python for what it does well, and just not want it unnecessarily slow. Commented Feb 25 at 19:11

You can do:

``````reduce(and_, (x==yourList[0] for x in yourList), True)
``````

It is fairly annoying that python makes you import the operators like `operator.and_`. As of python3, you will need to also import `functools.reduce`.

(You should not use this method because it will not break if it finds non-equal values, but will continue examining the entire list. It is just included here as an answer for completeness.)

``````lambda lst: reduce(lambda a,b:(b,b==a[0] and a[1]), lst, (lst[0], True))[1]
``````

The next one will short short circuit:

``````all(itertools.imap(lambda i:yourlist[i]==yourlist[i+1], xrange(len(yourlist)-1)))
``````
• Your first code was obviously wrong: `reduce(lambda a,b:a==b, [2,2,2])` yields `False`... I edited it, but this way it's not pretty anymore Commented Mar 27, 2014 at 9:41
• Does anyone understand how this is supposed to work? I looked at it for about a minute. The fact that I couldn't understand what it was supposed to be doing when I could read all of the other answers in a fraction of the time indicates this is not a good solution. Code smell Commented Feb 17 at 22:13
• @FreelanceConsultant Yes, I understand them :-). Pretty easy, though yes, the first one is relatively complicated (and no good). Commented Feb 18 at 3:24

Can use map and lambda

``````lst = [1,1,1,1,1,1,1,1,1]

print all(map(lambda x: x == lst[0], lst[1:]))
``````
• Is comparison slower than slicing (`==` slower than `1:`)? `all(map(lambda x: x == lst[0], lst))` Commented Jan 15, 2022 at 21:06
• This is really not great because you have a weird dependency on `lst[0]`. You are basically hoisting that value out of the enclosing scope. Commented Feb 17 at 22:12

Or use diff method of numpy:

``````import numpy as np
def allthesame(l):
return np.unique(l).shape[0]<=1
``````

And to call:

``````print(allthesame([1,1,1]))
``````

Output:

True

• There are many issues with this: It depends on numpy, requires extra work to transform the data into a `numpy` array, and will only work for specific sets of types. (Numerical things) Commented Feb 17 at 22:11

I suggest a simple pythonic solution:

``````def all_equal_in_iterable(iterable: Iterable):
iterable = list(iterable)
if not iterable:
return True
return all(item == iterable[0] for item in iterable)
``````

They're all equal if there aren't two groups.

``````from itertools import groupby, pairwise

def all_equal(iterable):
return not any(pairwise(groupby(iterable)))
``````

Attempt This Online!

You can also use the all_equal function from the handy more_itertools package.

``````pip install more_itertools
``````
``````>>> from more_itertools import all_equal
>>> all_equal((2, 2, 2, 1 + 1))
True
>>> all_equal((2, 2, 2, 0))
False
``````

If you're interested in something a little more readable (but of course not as efficient,) you could try:

``````def compare_lists(list1, list2):
if len(list1) != len(list2): # Weed out unequal length lists.
return False
for item in list1:
if item not in list2:
return False
return True

a_list_1 = ['apple', 'orange', 'grape', 'pear']
a_list_2 = ['pear', 'orange', 'grape', 'apple']

b_list_1 = ['apple', 'orange', 'grape', 'pear']
b_list_2 = ['apple', 'orange', 'banana', 'pear']

c_list_1 = ['apple', 'orange', 'grape']
c_list_2 = ['grape', 'orange']

print compare_lists(a_list_1, a_list_2) # Returns True
print compare_lists(b_list_1, b_list_2) # Returns False
print compare_lists(c_list_1, c_list_2) # Returns False
``````
• I'm actually trying to see if all elements in one list are identical; not if two separate lists are identical.
– max
Commented Jun 5, 2012 at 22:22
• This is also enormously inefficient; for an input of length N it takes N^2 steps.**At the very least**, if the values are hashable, use a set for the containment tests. Commented Nov 15, 2020 at 20:43
• I don't agree that this is "readable". It is very hard to understand what is going on here. You check that items in `list1` are in `list2` but do not do the reverse operation. So the logic is actually wrong anyway Commented Feb 17 at 22:15

You can use `.nunique()` to find number of unique items in a list.

``````def identical_elements(list):
series = pd.Series(list)
if series.nunique() == 1: identical = True
else:  identical = False
return identical

identical_elements(['a', 'a'])
Out[427]: True

identical_elements(['a', 'b'])
Out[428]: False
``````
• Yes, but `nunique` does too much work. Commented Jan 25, 2023 at 17:50
• This also has two additional problems: Dependency on `pandas`. Extra work done to create `Series` object Commented Feb 17 at 22:07

There is also a pure Python recursive option:

``````def checkEqual(lst):
if len(lst)==2 :
return lst[0]==lst[1]
else:
return lst[0]==lst[1] and checkEqual(lst[1:])
``````

However for some reason it is in some cases two orders of magnitude slower than other options. Coming from C language mentality, I expected this to be faster, but it is not!

The other disadvantage is that there is recursion limit in Python which needs to be adjusted in this case. For example using this.

• Recursive solutions blow up even for modest size inputs Commented Feb 17 at 22:10
• @FreelanceConsultant , thanks for your feedback, and I'm sorry if my answer does not meet your expectations. Please consider that this was never meant to be an optimum solution. I just added this for the completeness of the discussion. I have even admitted that this solution might be several orders of magnitude slower. Commented Feb 19 at 10:23
• You are not the first person to do this (obviously, as you can see there are many other answers which serve no purpose other than to suggest an alternative way of doing things.) Why? What is the point of this? It just obscures the better answers by filling the answers section with pages of "spam". The point of this site is not to demonstrate every possible way of doing something but to provide (ideally just one) good solution(s). If an answer has been posted, and you think of a better solution, then of course, you should post it. But posting things which are obviously worse - why? Commented Feb 20 at 9:20
• @FreelanceConsultant I don't think we share the definition of spam, nor do we agree about the function of this website. SO's business model is based on advertisement, and the more complete the keyword pool on this page, the more visits it gets. From the user's point of view, it is not just the best solution that benefits the visitors, IMHO, but also the less optimal ones. It induces discussion, as we see right now, and encourages critical thinking... anyway thanks for sharing your opinion, and I wish you the best. Commented Feb 20 at 9:52

Maybe I'm underestimating the problem? Check the length of unique values in the list.

``````lzt = [1,1,1,1,1,2]

if (len(set(lzt)) > 1):
uniform = False
elif (len(set(lzt)) == 1):
uniform = True
elif (not lzt):
raise ValueError("List empty, get wrecked")
``````
• I wouldn't be afraid of empty lists… can you say that no (zero count) (non)values are different to each other? Commented Jun 26, 2021 at 13:46
• Do you have an example? Commented Jun 26, 2021 at 13:48
``````l1 = [1, 2, 3, 4, 5]
l2 = [1] * 5
l3 = []
all_equal = lambda l: len(l) > 0 and all(l[0] == e for e in l)
print(f"{all_equal(l1) = }")  # False
print(f"{all_equal(l2) = }")  # True
print(f"{all_equal(l3) = }")  # False

``````