# Swapping 2 continuous strings - time complexity

Goal: Function, that takes a pointer to string and two lengths, and swaps between the inside strings represented by the lengths without using additional memory that depends on the size of the input. For example, given the string "abcdef123" and lengths 6,3 the result should be "123abcdef".

One possible recursive implementation (mine) is:

``````void invertStrings(char* str, int len1, int len2){
if(len1==0 || len2==0)
return;
if(len1>len2){
for(int i=0;i<len2;++i)
swapChars(str, len1+i, len1-len2+i);
invertStrings(str,len1-len2,len2);
}
else{
for(int i=0;i<len1;++i)
swapChars(str, len1+i, i);
invertStrings(str+len1,len1,len2-len1);
}
}
``````

I think that the time complexity is O(len1+len2) or maybe even something like O(max{len1,len2}).

Question: what is the time complexity and how could it be proven? Thanks.

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What is the function `sw`? –  user295691 Dec 31 '12 at 15:18
I would call this an in-place rotation. See cplusplus.com/reference/algorithm/rotate and replace "ForwardIterator" with "char*" in your head. Keep in mind that "last" is exclusive. –  sellibitze Dec 31 '12 at 15:24
@user295691: Sorry, this is a swap between two chars in the string. Fixed. –  Sanich Dec 31 '12 at 15:25
@sellibitze: Good reference. But, I i think while the complexity of it is O(n), it has some overhaed since every element is being swapped many times, and in my implementation most elements being swapped only once. In worst case (when len1 or len2 in 1) this would be very the same. –  Sanich Dec 31 '12 at 15:49

The algorithm as written appears to be `O(len1+len2)`. Let's define the "total work" of a function invocation as `len1 + len2`. Each time the function is called, it does `min(len1,len2)` swaps, and recursively invokes itself with `total_work[n+1] = total_work[n] - min(len1,len2)`. So an upper bound on the work done in all recursive invocations is just `len1+len2`.

The additional twist here is that the termination condition depends on `gcd(len1,len2)`. The loop terminates when one of len1,len2 are 0, so we're guaranteed that the number of swaps is strictly less than `len1+len2`. How much is "left over" at the end depends on the gcd of the two lengths. As an example, if we have `(6,3)` as the starting point, then we'll get `(6,3)->(3,3)->(0,3)`, for a total of 6 swaps (less than the 8 expected). But if we start with `(7,3)->(4,3)->(1,3)->(1,2)->(1,1)->(1,0)` we end up doing 9 swaps. The number of swaps in general is exactly `len1 + len2 - gcd(len1,len2)`.

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+1 for the exact number of steps :) –  KingsIndian Dec 31 '12 at 15:59
n=len1 + len2 ? –  Sanich Dec 31 '12 at 16:03
Yes, `n == len1+len2`. I will amend. –  user295691 Dec 31 '12 at 16:04
1)Is it an induction proof? –  Sanich Dec 31 '12 at 16:12
For generally analyzing running time of algorithms, you would use the so-called "Master Theorem"; in this case I cheated because the algorithm only uses tail recursion, so can be trivially transformed to an iterative solution, which is much easier to analyze. –  user295691 Dec 31 '12 at 16:33

It's O(n), because every swap operation puts at least one of the characters in it's correct final position.

Algorithmic complexity is a function of the size of the input and here the cost of the operation grows linearly with the size of the input.

Typically with complexity, you care only about the type of growth it exhibits. If it's linear, you don't care what the coefficient is (e.g., you don't care if it's two times the amount of input data or 7).

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I'm sorry I forgot that it should be implemented without additional memory. Edition made. –  Sanich Dec 31 '12 at 15:21
Oh, that makes quite a difference. –  Jeffrey Theobald Dec 31 '12 at 15:22
Would you please explain what do you mean by "order statements"? –  Sanich Dec 31 '12 at 15:23
It's a poor wording, I mean when people say O(n) or O(n^2) or O(nlogn) –  Jeffrey Theobald Dec 31 '12 at 15:25
It's not "order", it's "ordo", but that's just the name of the Greek letter. The property itself is called "algorithmic complexity" or "time complexity" or "computational complexity". –  user529758 Dec 31 '12 at 15:28