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If the above condition in a programming question is given and I am solving it using recursion then am I violating the constraints? It could be because recursion also uses stack? Is it right?

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Technically, if you have proper tail-call optimisation, then you can have a recursive solution to a problem, which only needs O(1) space on the stack, independent of the input. The recursion is then basically nothing but a loop. Scheme, for example, mandates tail-call elimination for, ah, tail-calls in all conforming implementations... –  Dirk Jun 23 at 8:34
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This is exactly why quicksort isn't truly an in-place algorithm (if, by in-place, you mean O(1) space complexity...). –  Bakuriu Jun 23 at 8:36
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@Bakuriu But quicksort can be programmed as a loop, and can be made O(1) space complexity, though it may lose in time complexity. See stackoverflow.com/questions/9096787/… –  becko Jun 23 at 22:24

6 Answers 6

up vote 27 down vote accepted

If the depth of the stack (recursion) is constant and does not change with respect to the size of the input, then a recursive solution can be O(1) extra space.

Some compilers may do tail call optimization (TCO) and remove recursive calls if they are the last statement executed in any given code path through a function. With TCO, there is no call-stack related memory overhead.

However, keep in mind that the O(1) constraint may be being imposed to force you to choose a particular (probably non-recursive) algorithm, so relying on tail call optimisation may be unwise even if you know the compiler you are using has made the relevant transformation to your code. At the very least, if you rely on it, you should say so explicitly and justify your expectation that TCO will occur by reference to language specifications, compiler documentation and/or disassembly as appropriate.

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That is an unusual kind of recursion, though. Usually it goes deeper as the input grows. –  Thilo Jun 23 at 7:34
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@Thilo An example is an operator precedence-based parser, where parse(9) calls parse(8) which calls parse(7) etc. for each precedence level of operators. –  hvd Jun 23 at 7:35
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@delnan, a search algo for a game may have a fixed number of calls if total number of moves is bounded. –  perreal Jun 23 at 7:39
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@delnan It's something I've really seen used in production code, at any rate. As for perreal's example, if a game always looks exactly (e.g.) four moves ahead, it can still be implemented with fixed-depth recursion. –  hvd Jun 23 at 7:48
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Tail recursion can also lead to no stack space being used for languages supporting tail call elimination. –  Tarik Jun 23 at 8:33

extra allowed space is O(1)

means that your program can use only a constant amount of space, say C.

Going by the definition of big-O, this means that the space that your program needs cannot depend on the size of the input, although C can be made arbitrarily large.

So if the recursion depends on the input a (which usually is the case), the space that your program needs is not O(1).

To clarify further :

A program which always uses 1 Mb uses O(1) space.

A program which always uses 1 Tb is using O(1) space b.

A program which uses N Mb, where N is the input does not use O(1) space, (it uses O(N) space).

Long story short, whenever you read O(1), just mentally replace it with constant.


a. For example, foo(n) = foo(n - 1), the stack space needed here to maintain the function calls is O(n)

b. When material on O notation comments on how the ignored constants can be troublesome, this is what they are talking about

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I very much like the comment on the 1Tb constant, I remember long ago asking a lecturer who taught us about the notation "Why can we not just calculate every possible input (up-to the program's max input size) into a table, then every problem could be O(1) for which at the time I got no answer. Or in the case of time why not just sleep for the time the worst case takes to ensure constant time. –  Vality Jun 23 at 12:13
    
@Vality: what was the lecturer's answer? I'm guessing it was that for theoretical purposes, there is no max input size; and for practical purposes, 'constant time' is not useful at the expense of speed. –  LarsH Jun 23 at 13:43
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@LarsH The lecturer at the time I believe said that that was a limitation of the system but then referred to Turing machines where the numbers could be arbitrarily large. He did however note my concern and said that we cannot blindly apply the notation without looking at practise and limitations. –  Vality Jun 23 at 15:00
    
There's no need to sleep; any program that always runs in less then x seconds is O(1), since there's a constant for which it's always smaller then. Technically speaking, on finite real-world machines, all terminating problems are O(1), since it takes a finite amount of time to cycle through all states. (Well, all problems, since the computer will break eventually.) That's just not a helpful way to approach algorithmic analysis. –  prosfilaes Jun 23 at 21:49
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This should probably go to chat, but for the record, Big-O is used to show how resource usage grows compared with input size. You can't just say "it always takes less than 10 years (or TB), therefore it's constant," because that doesn't tell you what happens as the input grows. Finitude is not the issue -- even if the problem itself dictated that the input size was bounded by some constant, you'd still want to know how certain algorithms performed as input size grew up to that constant. –  johncip Jun 24 at 3:04

If the depth of your recursion grows depending on the size of your input (which it usually does), then yes: You would be using an unbounded amount of stack memory. The requirement was to solve the problem with a fixed amount of memory.

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Regarding the other answers telling you that the amount of stack you must use is O(1), and must remain constant whatever the size of the input, if you wish to solve the problem in a recursive manner, it only leaves you with two possibilities:

  • Fixed-depth recursion, which means limiting the number of time the function is recursing.
  • Tail-recursion, which means that the recursive call to the function must be the last thing to be evaluated, so to trigger TCO. (tail call optimization) Roughly speaking, it means that since the recursive call is the last thing happening in funciton execution, instead of pushing the call context on the stack, the existing call context will be overwritten by the new one, effectively using a constant amount of stack space.
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It's also possible for algorithms to be "for all practical purposes" O(1) even if the stack depth is not strictly constant. A few data structures, for example, would require O(lg(lg(N)) stack space, and might require a collection's items to outnumber all the electrons in the universe before it reached a stack depth of ten. Such a thing wouldn't technically be O(1), but one could treat it as though it were. –  supercat Jun 23 at 22:00
    
@supercat: Good point. –  Laurent LA RIZZA Jun 24 at 7:16

If you are using recursion to solve this problem then you are using the stack to pass data down the recursion tree. In this regard you are typically using more than O(1) space.

I do agree with the accepted answer but I want to point out that if you are using a language with tail call optimization (like clojure) then you can solve problems with O(1) space which will use more space with a language which does not have this feature (like java).

So the right answer also depends on the language being used.

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While you can manually eliminate tail calls with recur there is no tail call optimization in clojure due to a limitation with the JVM. Related Answer –  Andrew T Jun 23 at 20:31

Storage Complexity of O(1) simply means you're algorithm must use a constant amount of storage. ie it must use the same amount of storage on a set of 10 elements as it does on 1000.

You should probably use iteration to accomplish this.

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