# Why does range(start, end) not include end?

``````>>> range(1,11)
``````

gives you

``````[1,2,3,4,5,6,7,8,9,10]
``````

Why not 1-11?

Did they just decide to do it like that at random or does it have some value I am not seeing?

• read Dijkstra, ewd831 Dec 21, 2010 at 22:52
• Basically you are choosing one set of off-by-one bugs for another. One set are more likely to cause your loops to terminate early, the other is likely to cause an Exception (or buffer overflow in other languages). Once you have written a bunch of code, you will see that the choice of behaviour `range()` has makes sense much more often Dec 21, 2010 at 23:34
• Link to Dijkstra, ewd831: cs.utexas.edu/users/EWD/ewd08xx/EWD831.PDF Dec 21, 2010 at 23:41
• @unutbu That Djikstra article is oft-cited in this topic but provides nothing of value here, people use it just as an appeal to authority. The only relevant pseudo-reason he gives for the OP's question is he happens to feel that including the upper bound becomes "unnatural" and "ugly" in the particular case where the sequence in empty - that's a wholly subjective position and easily argued against, so it doesn't bring much to the table. The "experiment" with Mesa isn't of much value either without knowing their particular constraints or evaluation methods. Oct 27, 2013 at 9:54
• @andreasdr But even if the cosmetic argument is valid, doesn't Python's approach introduce a new problem of readability? In common-usage English the term "range" implies that something ranges from something to something -- like an interval. That len(list(range(1,2))) returns 1 and len(list(range(2))) returns 2 is something you really have to learn to digest. Jul 24, 2016 at 14:11

Because it's more common to call `range(0, 10)` which returns `[0,1,2,3,4,5,6,7,8,9]` which contains 10 elements which equals `len(range(0, 10))`. Remember that programmers prefer 0-based indexing.

Also, consider the following common code snippet:

``````for i in range(len(li)):
pass
``````

Could you see that if `range()` went up to exactly `len(li)` that this would be problematic? The programmer would need to explicitly subtract 1. This also follows the common trend of programmers preferring `for(int i = 0; i < 10; i++)` over `for(int i = 0; i <= 9; i++)`.

If you are calling range with a start of 1 frequently, you might want to define your own function:

``````>>> def range1(start, end):
...     return range(start, end+1)
...
>>> range1(1, 10)
[1, 2, 3, 4, 5, 6, 7, 8, 9, 10]
``````
• If that were the reasoning wouldn't the parameters be `range(start, count)`? Dec 21, 2010 at 22:50
• @shogun The start value defaults to 0, i.e. `range(10)` is equivalent to `range(0, 10)`. Dec 21, 2010 at 22:57
• Your `range1` will not work with ranges that have a different step size than `1`. May 21, 2015 at 5:09
• You explain that range(x) should start with 0 and x will be the "length of the range". OK. But you didn't explain why range(x,y) should start with x and end with y-1. If the programmer wants a for-loop with i ranging from 1 to 3, he has to explicitly add 1. Is this really about convenience? Jul 24, 2016 at 14:42
• `for i in range(len(li)):` is rather an antipattern. One should use `enumerate`.
– hans
Mar 6, 2018 at 12:17

Although there are some useful algorithmic explanations here, I think it may help to add some simple 'real life' reasoning as to why it works this way, which I have found useful when introducing the subject to young newcomers:

With something like 'range(1,10)' confusion can arise from thinking that pair of parameters represents the "start and end".

It is actually start and "stop".

Now, if it were the "end" value then, yes, you might expect that number would be included as the final entry in the sequence. But it is not the "end".

Others mistakenly call that parameter "count" because if you only ever use 'range(n)' then it does, of course, iterate 'n' times. This logic breaks down when you add the start parameter.

So the key point is to remember its name: "stop". That means it is the point at which, when reached, iteration will stop immediately. Not after that point.

So, while "start" does indeed represent the first value to be included, on reaching the "stop" value it 'breaks' rather than continuing to process 'that one as well' before stopping.

One analogy that I have used in explaining this to kids is that, ironically, it is better behaved than kids! It doesn't stop after it supposed to - it stops immediately without finishing what it was doing. (They get this ;) )

Another analogy - when you drive a car you don't pass a stop/yield/'give way' sign and end up with it sitting somewhere next to, or behind, your car. Technically you still haven't reached it when you do stop. It is not included in the 'things you passed on your journey'.

I hope some of that helps in explaining to Pythonitos/Pythonitas!

• This explanation is more intuitive. Thanks
– Fred
Oct 10, 2019 at 2:50
• @bzip2, Python is not a pig, it's a serpent. What you call "inconsistencies" and "flaws" are not: they are design choices made by developers, carried consistently throughout the language and allowing millions of programmers to solve their tasks. If you don't like it, use an extension that provides inclusive ranges or switch to another language. Your comments do not contribute towards understanding Python, instead they offend the community. They also indicate your failure to understand the nature of exclusive intervals, because if you have a meeting from 9 to 11, at 11 you will be free. Jan 27, 2021 at 17:22
• Love the stop sign analogy, sorry to steal it :) Sep 20, 2021 at 10:58

Exclusive ranges do have some benefits:

For one thing each item in `range(0,n)` is a valid index for lists of length `n`.

Also `range(0,n)` has a length of `n`, not `n+1` which an inclusive range would.

It works well in combination with zero-based indexing and `len()`. For example, if you have 10 items in a list `x`, they are numbered 0-9. `range(len(x))` gives you 0-9.

Of course, people will tell you it's more Pythonic to do `for item in x` or `for index, item in enumerate(x)` rather than `for i in range(len(x))`.

Slicing works that way too: `foo[1:4]` is items 1-3 of `foo` (keeping in mind that item 1 is actually the second item due to the zero-based indexing). For consistency, they should both work the same way.

I think of it as: "the first number you want, followed by the first number you don't want." If you want 1-10, the first number you don't want is 11, so it's `range(1, 11)`.

If it becomes cumbersome in a particular application, it's easy enough to write a little helper function that adds 1 to the ending index and calls `range()`.

• Agree on slicing. `w = 'abc'; w[:] == w[0:len(w)]; w[:-1] == w[0:len(w)-1];` Dec 22, 2010 at 2:32
• `def full_range(start,stop): return range(start,stop+1) ## helper function` Aug 17, 2011 at 0:44

It's also useful for splitting ranges; `range(a,b)` can be split into `range(a, x)` and `range(x, b)`, whereas with inclusive range you would write either `x-1` or `x+1`. While you rarely need to split ranges, you do tend to split lists quite often, which is one of the reasons slicing a list `l[a:b]` includes the a-th element but not the b-th. Then `range` having the same property makes it nicely consistent.

The length of the range is the top value minus the bottom value.

It's very similar to something like:

``````for (var i = 1; i < 11; i++) {
//i goes from 1 to 10 in here
}
``````

in a C-style language.

Also like Ruby's range:

``````1...11 #this is a range from 1 to 10
``````

However, Ruby recognises that many times you'll want to include the terminal value and offers the alternative syntax:

``````1..10 #this is also a range from 1 to 10
``````

Consider the code

``````for i in range(10):
print "You'll see this 10 times", i
``````

The idea is that you get a list of length `y-x`, which you can (as you see above) iterate over.

Read up on the python docs for range - they consider for-loop iteration the primary usecase.

Basically in python `range(n)` iterates `n` times, which is of exclusive nature that is why it does not give last value when it is being printed, we can create a function which gives inclusive value it means it will also print last value mentioned in range.

``````def main():
for i in inclusive_range(25):
print(i, sep=" ")

def inclusive_range(*args):
numargs = len(args)
if numargs == 0:
raise TypeError("you need to write at least a value")
elif numargs == 1:
stop = args
start = 0
step = 1
elif numargs == 2:
(start, stop) = args
step = 1
elif numargs == 3:
(start, stop, step) = args
else:
raise TypeError("Inclusive range was expected at most 3 arguments,got {}".format(numargs))
i = start
while i <= stop:
yield i
i += step

if __name__ == "__main__":
main()
``````
• To avoid the possible surprise of an endless loop, I suggest to improve this code so that it works also in case of a negative step value. Mar 11 at 19:18

The `range(n)` in python returns from 0 to n-1. Respectively, the `range(1,n)` from 1 to n-1. So, if you want to omit the first value and get also the last value (n) you can do it very simply using the following code.

``````for i in range(1, n + 1):
print(i) #prints from 1 to n
``````

It's just more convenient to reason about in many cases.

Basically, we could think of a range as an interval between `start` and `end`. If `start <= end`, the length of the interval between them is `end - start`. If `len` was actually defined as the length, you'd have:

``````len(range(start, end)) == start - end
``````

However, we count the integers included in the range instead of measuring the length of the interval. To keep the above property true, we should include one of the endpoints and exclude the other.

Adding the `step` parameter is like introducing a unit of length. In that case, you'd expect

``````len(range(start, end, step)) == (start - end) / step
``````

for length. To get the count, you just use integer division.

• These defenses of Python's inconsistency are hilarious. If I wanted the interval between two numbers, why would I use subtraction to get the difference instead of the interval? It's inconsistent to use different indexing conventions for start and end positions. Why would you need to write "5:22" in order to get positions 5 to 21? Jan 17, 2020 at 22:33
• It's not Python's, it's pretty common across the board. In C, Java, Ruby, you name it Jan 17, 2020 at 22:52
• I meant to say that it's common for indexing, not that the other languages necessarily have the same exact kind of object Apr 9, 2020 at 18:56
• @Arseny in defence of Ruby, this is not true. You can construct inclusive and exclusive ranges in Ruby: `(3..5).include?(5) => true` but `(3...5).include?(5) => false`. Array slicing is explicit and inclusive: `[0,1,2,3,4].slice(0,2) => [0, 1]`. You can even construct open ranges: `r = 42..; r.include?(Float::INFINITY) => true` Feb 23 at 16:04
• @AndreasGebhard, no doubt there are cases when that's convenient. Scala, for instance, has both `a to b` and `a until b`. My point is that excluding the right end of the range is common practice and isn't an inconsistency whatsoever. Also, historically, the `<` comparison is faster for the processor than the `<=` comparison Feb 23 at 18:29