I was playing around in python. I used the following code in IDLE:

p  = [1, 2]
p[1:1] = [p]
print p

The output was:

[1, [...], 2]

What is this […]? Interestingly I could now use this as a list of list of list up to infinity i.e.


I could write the above as long as I wanted and it would still work.


  • How is it represented in memory?
  • What's its use? Examples of some cases where it is useful would be helpful.
  • Any link to official documentation would be really useful.
  • 7
    A simpler example would be p = [1]; p[0] = p.
    – arshajii
    Commented Jun 18, 2013 at 14:12
  • 6
    I think this is a duplicate of What does […] (an ellipsis) in a list mean in Python?, although the question (and answers) are better in this question. Commented Jun 18, 2013 at 20:08
  • 1
    Dreampie is smart ` >>> p[1:1] = [p] >>> p 3: [1, <Recursion on list with id=3074777548>, 2] >>> ` provide the exact detail Commented Jun 20, 2013 at 9:40
  • @RahulGautam Didn't get this p 3: [1, <Recursion on list with id=3074777548>, 2]. What did you run? Commented Jun 20, 2013 at 10:27
  • id=3074777548 is the id of p so its easy to understand that its referring to itself. Anyway very nice question @Zel Commented Jun 25, 2013 at 9:23

5 Answers 5


This is what your code created

enter image description here

It's a list where the first and last elements are pointing to two numbers (1 and 2) and where the middle element is pointing to the list itself.

In Common Lisp when printing circular structures is enabled such an object would be printed as

#1=#(1 #1# 2)

meaning that there is an object (labelled 1 with #1=) that is a vector with three elements, the second being the object itself (back-referenced with #1#).

In Python instead you just get the information that the structure is circular with [...].

In this specific case the description is not ambiguous (it's backward pointing to a list but there is only one list so it must be that one). In other cases may be however ambiguous... for example in

[1, [2, [...], 3]]

the backward reference could either point to the outer or to the inner list. These two different structures printed in the same way can be created with

x = [1, [2, 3]]
x[1][1:1] = [x[1]]

y = [1, [2, 3]]
y[1][1:1] = [y]


and they would be in memory as

enter image description here

  • You can find the contents of the [1, [2, [...], 3]] like this: x[1] = [2, [...], 3] and y[1] = [2, 1, [...]], 3]. This means that x consists of a 1 and then repeating 2s, whereas y consists of alternating 1s and 2s.
    – pascalhein
    Commented Jun 18, 2013 at 14:51
  • 3
    @csharpler: of course you can distinguish the two by analyzing the content, however they are printed with the same representation. In Common Lisp format instead they would be #(1 #1=#(2 #1# 3)) for x and #1=#(1 #(2 #1# 3)) for y.
    – 6502
    Commented Jun 18, 2013 at 17:37
  • 6
    @BurhanKhalid: inkscape for the first and gimp for the second (because I threw away the svg)
    – 6502
    Commented Jun 18, 2013 at 20:01
  • 1
    @csharpler: you cannot create an "infinite list" in Python because lists are indeed resizable arrays, not linked lists. An "infinite list" in Common Lisp could instead be created with #1=(1 . #1#).
    – 6502
    Commented Jun 18, 2013 at 20:09
  • 2
    + if you wants to draw acsii-diagram like this try: Asiiflow Commented Jul 20, 2013 at 14:24

It means that you created an infinite list nested inside itself, which can not be printed. p contains p which contains p ... and so on. The [...] notation is a way to let you know this, and to inform that it can't be represented! Take a look at @6502's answer to see a nice picture showing what's happening.

Now, regarding the three new items after your edit:

  • This answer seems to cover it
  • Ignacio's link describes some possible uses
  • This is more a topic of data structure design than programming languages, so it's unlikely that any reference is found in Python's official documentation
  • So is it taking infinte memory? I know that cannot be possible. How is it represented and what's its use? Commented Jun 18, 2013 at 3:42
  • 21
    @Zel: List elements are references. The second element is a reference to the list itself. Commented Jun 18, 2013 at 3:43
  • 2
    Python it identified it as an infinite loop of references, so it decided to cut it short, it's not really infinite. And no, it's not really useful besides a thought experiment :) Commented Jun 18, 2013 at 3:44
  • 2
    There are... a few uses for infinitely recursive structures. But not many. Commented Jun 18, 2013 at 3:45
  • @IgnacioVazquez-Abrams Some examples would be useful. Commented Jun 18, 2013 at 3:46

To the question "What's its use", here is a concrete example.

Graph reduction is an evaluation strategy sometime used in order to interpret a computer language. This is a common strategy for lazy evaluation, notably of functional languages.

The starting point is to build a graph representing the sequence of "steps" the program will take. Depending on the control structures used in that program, this might lead to a cyclic graph (because the program contains some kind of "forever" loop -- or use recursion whose "depth" will be known at evaluation time, but not at graph-creation time)...

In order to represent such graph, you need infinite "data structures" (sometime called recursive data structures), like the one you noticed. Usually, a little bit more complex though.

If you are interested in that topic, here is (among many others) a lecture on that subject:


We do this all the time in object-oriented programming. If any two objects refer to each other, directly or indirectly, they are both infinitely recursive structures (or both part of the same infinitely recursive structure, depending on how you look at it). That's why you don't see this much in something as primitive as a list -- because we're usually better off describing the concept as interconnected "objects" than an "infinite list".

You can also get ... with an infinitely recursive dictionary. Let's say you want a dictionary of the corners of a triangle, where each value is a dictionary of the other corners connected to that corner. You could set it up like this:

a = {}
b = {}
c = {}
triangle = {"a": a, "b": b, "c": c}
a["b"] = b
a["c"] = c
b["a"] = a
b["c"] = c
c["a"] = a
c["b"] = b

Now if you print triangle (or a or b or c for that matter), you'll see it's full of {...} because any two corners are referring to back to each other.

  • Simpler dictionary example: a = {}; a['a'] = a; print a['a']['a']['a']
    – user650654
    Commented Jun 19, 2013 at 7:27
  • 1
    For me, instead of "..." it shows "<Recursion on dict with id=___>" Commented Apr 17, 2016 at 23:30
  • 3
    @SolomonUcko You're probably using IPython which automatically uses pprint to print things. If you type %pprint to toggle pretty-printing off, it will show ....
    – nmclean
    Commented Apr 18, 2016 at 13:36

As I understood, this is an example of fixed point

p  = [1, 2]
p[1:1] = [p]
f = lambda x:x[1]
  • I haven't been able to understand this. Tried to run these commands but there are errors. Commented Jun 19, 2013 at 5:17
  • @Zel: Well, you have to add OPs code before it so that p is declared.
    – Inkane
    Commented Jun 19, 2013 at 9:07
  • 1
    @Zel: Well, I'm not sure how helpful it is myself, but Firegun says that p (and therefore p[1], represented as [...]) is a fixpoint of the function f. IMHO, this is a possible answer of the question "What is [...]?" in this case.
    – Inkane
    Commented Jun 19, 2013 at 9:39
  • 1
    I had the same error issue because I had tried this example after trying the simpler p = [1]; p[0] = p example which needs f = lambda x:x[0] to work. It is an example of a fix point, but I have not yet been able to see how knowing this is useful. The real value of the fix point is arriving at it from some other point in a recursive or iterative manner. An example that shows how to use the list structure of the original question to create the Y combinator would be helpful if it is possible.
    – dansalmo
    Commented Jun 19, 2013 at 15:09
  • 1
    q = lambda: q makes an infinitely callable lambda Commented Aug 4, 2018 at 14:57

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.