# Are there any O(1/n) algorithms?

Are there any O(1/n) algorithms?

Or anything else which is less than O(1)?

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That is the commonly understood definition of "O(X) algorithm" in computer science: an algorithm whose time complexity is O(X) (for some expression X). –  David Z Jul 9 '10 at 1:17
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This question isn't as stupid as it might seem. At least theoretically, something such as O(1/n) is completely sensible when we take the mathematical definition of the Big O notation:

Now you can easily substitute g(x) for 1/x … it's obvious that the above definition still holds for some f.

For the purpose of estimating asymptotic run-time growth, this is less viable … a meaningful algorithm cannot get faster as the input grows. Sure, you can construct an arbitrary algorithm to fulfill this, e.g. the following one:

``````def get_faster(list):
how_long = (1 / len(list)) * 100000
sleep(how_long)
``````

Clearly, this function spends less time as the input size grows … at least until some limit, enforced by the hardware (precision of the numbers, minimum of time that `sleep` can wait, time to process arguments etc.): this limit would then be a constant lower bound so in fact the above function still has runtime O(1).

But there are in fact real-world algorithms where the runtime can decrease (at least partially) when the input size increases. Note that these algorithms will not exhibit runtime behaviour below O(1), though. Still, they are interesting. For example, take the very simple text search algorithm by Horspool. Here, the expected runtime will decrease as the length of the search pattern increases (but increasing length of the haystack will once again increase runtime).

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'Enforced by the hardware' also applies to a Turing Machine. In case of O(1/n) there will always be an input size for which the algorithm is not supposed to execute any operation. And therefore I would think that O(1/n) time complexity is indeed impossible to achieve. –  Roland Ewald May 25 '09 at 14:10
Mehrdad, you don't understand. The O notation is something about the limit (technically lim sup) as n -> ∞. The running time of an algorithm/program is the number of steps on some machine, and is therefore discrete -- there is a non-zero lower bound on the time that an algorithm can take ("one step"). It is possible that upto some finite N a program takes a number of steps decreasing with n, but the only way an algorithm can be O(1/n), or indeed o(1), is if it takes time 0 for all sufficiently large n -- which is not possible. –  ShreevatsaR May 25 '09 at 20:04
We are not disagreeing that O(1/n) functions (in the mathematical sense) exist. Obviously they do. But computation is inherently discrete. Something that has a lower bound, such as the running time of a program -- on either the von Neumann architecture or a purely abstract Turing machine -- cannot be O(1/n). Equivalently, something that is O(1/n) cannot have a lower bound. (Your "sleep" function has to be invoked, or the variable "list" has to be examined -- or the input tape has to be examined on a Turing machine. So the time taken would change with n as some ε + 1/n, which is not O(1/n)) –  ShreevatsaR May 26 '09 at 0:14
If T(0)=∞, it doesn't halt. There is no such thing as "T(0)=∞, but it still halts". Further, even if you work in R∪{∞} and define T(0)=∞, and T(n+1)=T(n)/2, then T(n)=∞ for all n. Let me repeat: if a discrete-valued function is O(1/n), then for all sufficiently large n it is 0. [Proof: T(n)=O(1/n) means there exists a constant c such that for n>N0, T(n)<c(1/n), which means that for any n>max(N0,1/c), T(n)<1, which means T(n)=0.] No machine, real or abstract, can take 0 time: it has to look at the input. Well, besides the machine that never does anything, and for which T(n)=0 for all n. –  ShreevatsaR May 27 '09 at 3:50
You have to like any answer that begins "This question isn't as stupid as it might seem." –  Telemachus Jun 27 '09 at 12:53
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I think the source of the debate is possibly the misconception of Big-Oh and Big-theta notations.

In some answers and comments it was mentioned that a `O(1/n)` can be considered `O(1)` as the function is already bounded to some constant. This is true and indeed, it's the nature of Big-Oh notation. You can say QuickSort is O(n100) and you are technically correct as it's a valid upper bound (which is not very tight in this example).

As a result, technically, this question is obvious: If anything is less than O(1) (or O(whatever), for that matter), it would also be O(1) (O(`>` whatever)), by definition.

In regular speech, we mostly use Big-Oh to mean tight bounds (instead of Big-theta, which is the correct notation for it). Basically, the question should not include the "or anything less than O(1)" part. Konrad's answer is completely right.

These notations are theoretical concepts. They don't take one important thing into account that currently limits us in practice: In practice, our machines are finite and this is where it seems like a paradox. In a finite machine, our "`n`" always has an upper bound. Therefore "`1/n`" will have a lower bound which is a constant. So the algorithm practically looks `O(1)` in all finite state machines but because our n can never become big enough.

To those who believe that there are no `o(1)` (small-oh) algorithms in practice (as mentioned in some answers), I can argue that in practice all algorithms that eventually halt are also `O(1)`. With the similar reasoning mentioned above, because the input itself is always bounded, any function of input will also be bounded (it can be very large, but it still has a constant bound!), so every algorithm is `O(1)` in finite machines. (Put it differently, pigeonhole principle implies that every deterministic finite state machine with `S` different states can have at most `S` transitions before getting back to the original state. So any algorithm that eventually halts, which should not make the machine return to the start state, can have at most `S-1` state transitions, so every algorithm will be O(1)).

As pointed out in the comments, computation, as defined by the Turing machine model, is inherently discrete. That will imply that `1/n` algorithms cannot exist in a discrete computational model. My point is, when using the asymptotic growth about practical implementation of algorithms, we are already ignoring some limitations (for good reasons). There can be algorithms with decreasing running times (till it reaches a bound, of course) as the input grows (as Konrad said). Similarly, one may skew the use of notation to describe the running time of an implementation of such an algorithm.

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Really good explanation and more complete than mine. –  Konrad Rudolph May 25 '09 at 14:45
True, all algorithms in practice (on finite machines / with bounded tape) are O(1), but this is irrelevant. There are no o(1) algorithms either in practice or in theory. –  ShreevatsaR May 25 '09 at 20:10
"I can argue that in practice all algorithms that eventually halt are also O(1)!" And I can argue that breaking a 4096-bit RSA key pair in practice takes exponential time ;-) –  Jonas Kölker May 26 '09 at 3:10
Many good points, but I think your first part is not actually relevant: yes, any function that is O(1/n) is also O(1) (and O(n^100)), but that is not the question -- the question is, do any O(1/n) algorithms exist? (I.e. the question is about the converse situation, and your reasoning says nothing about that. E.g. it certainly does not follow that any O(1) algorithm is also O(1/n).) –  j_random_hacker May 26 '09 at 11:29
-1: No algorithm can be O(1/n) unless it is willing to take 0 time to answer a question. So, no, its not about a difference in theory and practice. It is true that all algorithms are "in practice" O(1) in the way you have defined, but that way is almost meaningless. The whole point of O notation is to measure growth - your results lead to no meaningful conclusions –  Casebash Jul 9 '10 at 4:56
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Yes.

There is precisely one algorithm with runtime O(1/n), the "empty" algorithm.

For an algorithm to be O(1/n) means that it executes asymptotically in less steps than the algorithm consisting of a single instruction. If it executes in less steps than one step for all n > n0, it must consist of precisely no instruction at all for those n. Since checking 'if n > n0' costs at least 1 instruction, it must consist of no instruction for all n.

Summing up: The only algorithm which is O(1/n) is the empty algorithm, consisting of no instruction.

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This is the only correct answer in this thread, and (despite my upvote) it is at zero votes. Such is StackOverflow, where "correct-looking" answers are voted higher than actually correct ones. –  ShreevatsaR Feb 24 '10 at 17:15
No, its rated 0 because it is incorrect. Expressing a big-Oh value in relation to N when it is independent of N is incorrect. Second, running any program, even one that just exists, takes at least a constant amount of time, O(1). Even if that wasn't the case, it'd be O(0), not O(1/n). –  kenj0418 Feb 28 '10 at 17:16
Any function that is O(0) is also O(1/n), and also O(n), also O(n^2), also O(2^n). Sigh, does no one understand simple definitions? O() is an upper bound. –  ShreevatsaR Apr 15 '10 at 3:52
@kenj0418 You managed to be wrong in every single sentence. "Expressing a big-Oh value in relation to N when it is independent of N is incorrect." A constant function is a perfectly goof function. "Second, running any program, even one that just exists, takes at least a constant amount of time, O(1)." The definition of complexity doesn't say anything about actually running any programs. "it'd be O(0), not O(1/n)". See @ShreevatsaR's comment. –  Alexey Romanov Aug 24 '10 at 20:12
it seems that you are not plumber. good answer. –  dfens Oct 30 '10 at 22:47
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That's not possible. The definition of Big-O is the not greater than inequality:

``````A(n) = O(B(n)) <=> exists constant C, C > 0 such that for all n A <= C*B
``````

So the B(n) is in fact the maximum value, therefore if it decreases as n increases the estimation will not change.

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I suspect this answer is the "right one", but unfortunately I lack the intellect to understand it. –  freespace May 25 '09 at 6:24
AFAIK this condition does not have to be true for all n, but for all n > n_0 (i.e., only when the size of the input reaches a specific threshold). –  Roland Ewald May 25 '09 at 7:37
I don't see how the definition (even corrected) contradicts the question of the OP. The definition holds for completely arbitrary functions! 1/n is a completely sensible function for B, and in fact your equation doesn't contradict that (just do the math). So no, despite much consensus, this answer is in fact wrong. Sorry. –  Konrad Rudolph May 25 '09 at 8:00
Wrong! I don't like downvoting but you state that this is impossible when there is no clear consensus. In practice you are correct, if you do construct a function with 1/n runtime (easy) it will eventually hit the some minimum time, effectively making it an O(1) algorithm when implemented. There is nothing to stop the algorithm from being O(1/n) on paper though. –  jheriko May 25 '09 at 9:56
@Jason: Yep, now that you say it... :) @jheriko: A time complexity of O(1/n) does not work on paper IMHO. We're characterizing the growth function f(input size) = #ops for a Turing machine. If it does halt for an input of length n=1 after x steps, then I will choose an input size n >> x, i.e. large enough that, if the algorithm is indeed in O(1/n), no operation should be done. How should a Turing machine even notice this (it's not allowed to read once from the tape)? –  Roland Ewald May 25 '09 at 13:54
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sharptooth is correct, O(1) is the best possible performance. However, it does not imply a fast solution, just a fixed time solution.

An interesting variant, and perhaps what is really being suggested, is which problems get easier as the population grows. I can think of 1, albeit contrived and tongue-in-cheek answer:

Do any two people in a set have the same birthday? When n exceeds 365, return true. Although for less than 365, this is O(n ln n). Perhaps not a great answer since the problem doesn't slowly get easier but just becomes O(1) for n > 365.

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366. Don't forget about leap years! –  Nick Johnson May 25 '09 at 12:17
You are correct. Like computers, I am occasionally subject to rounding errors :-) –  Adrian May 26 '09 at 0:14
+1. There are a number of NP-complete problems that undergo a "phase transition" as n increases, i.e. they quickly become much easier or much harder as you exceed a certain threshold value of n. One example is the Number Partitioning Problem: given a set of n nonnegative integers, partition them into two parts so that the sum of each part is equal. This gets dramatically easier at a certain threshold value of n. –  j_random_hacker May 26 '09 at 11:34

From my previous learning of big O notation, even if you need 1 step (such as checking a variable, doing an assignment), that is O(1).

Note that O(1) is the same as O(6), because the "constant" doesn't matter. That's why we say O(n) is the same as O(3n).

So if you need even 1 step, that's O(1)... and since your program at least needs 1 step, the minimum an algorithm can go is O(1). Unless if we don't do it, then it is O(0), I think? If we do anything at all, then it is O(1), and that's the minimum it can go.

(If we choose not to do it, then it may become a Zen or Tao question... in the realm of programming, O(1) is still the minimum).

programmer: boss, I found a way to do it in O(1) time!
boss: no need to do it, we are bankrupt this morning.
programmer: oh then, it becomes O(0).

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What about not running the function at all (NOOP)? or using a fixed value. Does that count?

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That's still O(1) runtime. –  Konrad Rudolph May 25 '09 at 8:10
Right, that's still O(1). I don't see how someone can understand this, and yet claim in another answer that something less than NO-OP is possible. –  ShreevatsaR May 25 '09 at 20:21
ShreevatsaR: there is absolutely no contradiction. You seem to fail to grasp that big O notation has got nothing to do with the time spent in the function – rather, it describes how that time changes with changing input (above a certain value). See other comment thread for more. –  Konrad Rudolph May 25 '09 at 20:42
Yes... as I said elsewhere, any algorithm that is O(1/n) should also take zero time for all inputs, so depending on whether you consider the null algorithm to take 0 time or not, there is an O(1/n) algorithm. So if you consider NOOP to be O(1), then there are no O(1/n) algorithms. –  ShreevatsaR Jul 9 '10 at 16:51
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O(1) simply means "constant time".

When you add an early exit to a loop[1] you're (in big-O notation) turning an O(1) algorithm into O(n), but making it faster.

The trick is in general the constant time algorithm is the best, and linear is better then exponential, but for small amounts of n, the exponential algorith might actually be faster.

1: Assuming a static list length for this example

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No, this is not possible:

As n tends to infinity in 1/n we eventually achieve 1/(inf), which is effectively 0.

Thus, the big-oh class of the problem would be O(0) with a massive n, but closer to constant time with a low n. This is not sensible, as the only thing that can be done in faster than constant time is:

`void nothing() {};`

And even this is arguable!

As soon as you execute a command, you're in at least O(1), so no, we cannot have a big-oh class of O(1/n)!

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I often use O(1/n) to describe probabilities that get smaller as the inputs get larger -- for example, the probability that a fair coin comes up tails on log2(n) flips is O(1/n).

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That's not what big O is though. You can't just redefine it in order to answer the question. –  Zifre May 25 '09 at 20:11
It's not a redefinition, it's exactly the definition of big O. –  ShreevatsaR May 25 '09 at 20:18
I am a theoretical computer scientist by trade. It's about the asymptotic order of a function. –  Dave May 25 '09 at 23:03
Big O is a property of an arbitrary real function. Time complexity is just one of its possible applications. Space complexity (the amount of working memory an algorithm uses) is another. That the question is about O(1/n) algorithms implies that it's one of these (unless there's another that applies to algorithms that I don't know about). Other applications include orders of population growth, e.g. in Conway's Life. See also en.wikipedia.org/wiki/Big_O_notation –  Stewart Aug 17 '09 at 15:51
@Dave: The question wasn't whether there exist O(1/n) functions, which obviously do exist. Rather, it was whether there exist O(1/n) algorithms, which (with the possible exception of the null function) can't exist –  Casebash Jul 9 '10 at 10:58
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I believe quantum algorithms can do multiple computations "at once" via superposition...

I doubt this is a useful answer.

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But what if the problem was a pale ale? (ah. hah. ha.) –  Jeff Meatball Yang May 25 '09 at 6:31
That would be a super position to be in. –  Daniel Earwicker May 25 '09 at 7:27
Quantum algorithms can do multiple computations, but you can only retrieve the result of one computation, and you can't choose which result to get. Thankfully, you can also do operations on a quantum register as a whole (for example, QFT) so you're much likelier to find something :) –  Gracenotes May 25 '09 at 8:02
I agree. This isn't useful. –  Casebash Jul 9 '10 at 4:33
it's perhaps not useful, but it has the advantage of being true, which puts it above some of the more highly voted answers B-) –  Brian Postow Jul 9 '10 at 19:20
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many people have had the correct answer (No) Here's another way to prove it: In order to have a function, you have to call the function, and you have to return an answer. This takes a certain constant amount of time. EVEN IF the rest of the processing took less time for larger inputs, printing out the answer (Which is we can assume to be a single bit) takes at least constant time.

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If solution exists, it can be prepared and accessed in constant time=immediately. For instance using a LIFO data structure if you know the sorting query is for reverse order. Then data is already sorted, given that the appropriate model (LIFO) was chosen.

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Which problems get easier as population grows? One answer is a thing like bittorrent where download speed is an inverse function of number of nodes. Contrary to a car, which slows down the more you load it, a file-sharing network like bittorrent speeds the more nodes connected.

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You can't go below O(1), however O(k) where k is less than N is possible. We called them sublinear time algorithms. In some problems, Sublinear time algorithm can only gives approximate solutions to a particular problem. However, sometimes, an approximate solutions is just fine, probably because the dataset is too large, or that it's way too computationally expensive to compute all.

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Not sure I understand. Log(N) is less than N. Does that mean that Log(N) is a sublinear algorithm? And many Log(N) algorithms do exist. One such example is finding a value in a binary tree. However, these are still different than 1/N, Since Log(N) is always increasing, while 1/n is a decreasing function. –  Kibbee May 25 '09 at 14:41
Uh, sublinear time algorithms can give exact answers, e.g. binary search in an ordered array on a RAM machine. –  A. Rex May 28 '09 at 0:39
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O(1/n) is not less then O(1), it basically means that the more data you have, the faster algorithm goes. Say you get an array and always fill it in up to a 10100 elements if it has less then that and do nothing if there's more. This one is not O(1/n) of course but something like O(-n) :) Too bad O-big notation does not allow negative values.

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"O(1/n) is not less then O(1)" -- if a function f is O(1/n), it's also O(1). And big-oh feels a lot like a "lesser than" relation: it's reflexive, it's transitive, and if we have symmetry between f and g the two are equivalent, where big-theta is our equivalence relation. ISTR "real" ordering relations requiring a <= b and b <= a to imply a = b, though, and netcraft^W wikipedia confirms it. So in a sense, it's fair to say that indeed O(1/n) is "less than" O(1). –  Jonas Kölker May 26 '09 at 3:15
``````inline void O0Algorithm() {}
``````
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That as well, but the point is that it isn't Ω(1). And why has my answer been downrated? If you think I'm wrong, how about explaining? –  Stewart Feb 16 '10 at 13:55
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In numerical analysis, approximation algorithms should have sub-constant asymptotic complexity in the approximation tolerance.

``````class Function
{
public double[] ApproximateSolution(double tolerance)
{
// if this isn't sub-constant on the parameter, it's rather useless
}
}
``````
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It may be possible to construct an algorithm that is O(1/n). One example would be a loop that iterates some multiple of f(n)-n times where f(n) is some function whose value is guaranteed to be greater than n and the limit of f(n)-n as n approaches infinity is zero. The calculation of f(n) would also need to be constant for all n. I do not know off hand what f(n) would look like or what application such an algorithm would have, in my opinion however such a function could exist but the resulting algorithm would have no purpose other than to prove the possibility of an algorithm with O(1/n).

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OK, I did a bit of thinking about it, and perhaps there exists an algorithm that could follow this general form:

You need to compute the traveling salesman problem for a 1000 node graph, however, you are also given a list of nodes which you cannot visit. As the list of unvisitable nodes grows larger, the problem becomes easier to solve.

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It's different kind of n in the O(n) then. With this trick you could say every algorithm has O(q) where q is number of people living in China for example. –  vava May 25 '09 at 6:35
Boyer-Moore is of a similar kind (O(n/m)), but that's not really "better than O(1)", because n >= m. I think the same is true for your "unvisitable TSP". –  Niki May 25 '09 at 6:39
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I see an algorithm that is O(1/n) admittedly to an upper bound:

You have a large series of inputs which are changing due to something external to the routine (maybe they reflect hardware or it could even be some other core in the processor doing it.) and you must select a random but valid one.

Now, if it wasn't changing you would simply make a list of items, pick one randomly and get O(1) time. However, the dynamic nature of the data precludes making a list, you simply have to probe randomly and test the validity of the probe. (And note that inherently there is no guarantee the answer is still valid when it's returned. This still could have uses--say, the AI for a unit in a game. It could shoot at a target that dropped out of sight while it was pulling the trigger.)

This has a worst-case performance of infinity but an average case performance that goes down as the data space fills up.

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As has been pointed out, apart from the possible exception of the null function, there can be no `O(1/n)` functions, as the time taken will have to approach 0.

Of course, there are some algorithms, like that defined by Konrad, which seem like they should be less than `O(1)` in at least some sense.

``````def get_faster(list):
how_long = 1/len(list)
sleep(how_long)
``````

If you want to investigate these algorithms, you should either define your own asymptotic measurement, or your own notion of time. For example, in the above algorithm, I could allow the use of a number of "free" operations a set amount of times. In the above algorithm, if I define t' by excluding the time for everything but the sleep, then t'=1/n, which is O(1/n). There are probably better examples, as the asymptotic behavior is trivial. In fact, I am sure that someone out there can come up with senses that give non-trivial results.

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I had such a doubt way back in 2007, nice to see this thread, i came to this thread from my reddit thread -> http://www.reddit.com/r/programming/comments/d4i8t/trying_to_find_an_algorithm_with_its_complexity/

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``````void FindRandomInList(list l)
{
while(1)
{
int rand = Random.next();
if (l.contains(rand))
return;
}
}
``````

as the size of the list grows, the expected runtime of the program decreases.

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If the answer is the same regardless of the input data then you have an O(0) algorithm.

or in other words - the answer is known before the input data is submitted - the function could be optimised out - so O(0)

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no, O(0) would imply it takes zero time for all inputs. O(1) is constant time. –  Pete Kirkham May 25 '09 at 8:51
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Big-O notation represents the worst case scenario for an algorithm which is not the same thing as its typical run time. It is simple to prove that an O(1/n) algorithm is an O(1) algorithm . By definition,
O(1/n) --> T(n) <= 1/n, for all n >= C > 0
O(1/n) --> T(n) <= 1/C, Since 1/n <= 1/C for all n >=C
O(1/n) --> O(1), since Big-O notation ignores constants (i.e. the value of C doesn't matter)

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Roland: That's a misconception; upper bound is not the same thing as worst-case, the two are independent concepts. Consider the expected (and average) runtime of the `hashtable-contains` algorithm which can be denoted as O(1) -- and the worst case can be given very precisely as Theta(n)! Omega and Theta may simply be used to denote other bounds but to say it again: they have got nothing to do with average or best case. –  Konrad Rudolph May 25 '09 at 14:17
The fact that O(1/n) is a subset of O(1) is trivial and follows directly from the definition. In fact, if a function g is O(h), then any function f which is O(g) is also O(h). –  Tobias Jun 11 '09 at 17:43
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Nothing is smaller than O(1) Big-O notation implies the largest order of complexity for an algorithm

If an algorithm has a runtime of n^3 + n^2 + n + 5 then it is O(n^3) The lower powers dont matter here at all because as n -> Inf, n^2 will be irrelevant compared to n^3

Likewise as n -> Inf, O(1/n) will be irrelevant compared to O(1) hence 3 + O(1/n) will be the same as O(1) thus making O(1) the smallest possible computational complexity

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Here's a simple O(1/n) algorithm. And it even does something interesting!

``````function foo(list input) {
int m;
double output;

m = (1/ input.size) * max_value;
output = 0;
for (int i = 0; i < m; i++)
output+= random(0,1);

return output;
}
``````

O(1/n) is possible as it describes how the output of a function changes given increasing size of input. If we are using the function 1/n to describe the number of instructions a function executes then there is no requirement that the function take zero instructions for any input size. Rather, it is that for every input size, n above some threshold, the number of instructions required is bounded above by a positive constant multiplied by 1/n. As there is no actual number for which 1/n is 0, and the constant is positive, then there is no reason why the function would constrained to take 0 or fewer instructions.

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Since O(1/n) will fall below the horizontal line =1, and when n reaches infinite, your code will still execute a given number of steps, this algorithm is an O(1) algorithm. Big-O notation is a function of all the different parts of the algorithm, and it picks the biggest one. Since the method will always run some of the instructions, when n reaches infinite, you're left with those same instructions executing every time, and thus the method will then run in constant time. Granted, it won't be much time, but that's not relevant to Big-O notation. –  Lasse V. Karlsen Jan 23 '10 at 23:55