For general use, solutions involving the StringBuilder class are best for repeating multi-character strings. It's optimized to handle the combination of large numbers of strings in a way that simple concatenation can't and that would be difficult or impossible to do more efficiently by hand. The StringBuilder solutions shown here use O(N) iterations to complete, a flat rate proportional to the number of times it is repeated.
However, for very large number of repeats, or where high levels of efficiency must be squeezed out of it, a better approach is to do something similar to StringBuilder's basic functionality but to produce additional copies from the destination, rather than from the original string, as below.
public static string Repeat_CharArray_LogN(this string str, int times)
int limit = (int)Math.Log(times, 2);
char buffer = new char[str.Length * times];
int width = str.Length;
Array.Copy(str.ToCharArray(), buffer, width);
for (int index = 0; index < limit; index++)
Array.Copy(buffer, 0, buffer, width, width);
width *= 2;
Array.Copy(buffer, 0, buffer, width, str.Length * times - width);
return new string(buffer);
This doubles the length of the source/destination string with each iteration, which saves the overhead of resetting counters each time it would go through the original string, instead smoothly reading through and copying the now much longer string, something that modern processors can do much more efficiently.
It uses a base-2 logarithm to find how many times it needs to double the length of the string and then proceeds to do so that many times. Since the remainder to be copied is now less than the total length it is copying from, it can then simply copy a subset of what it has already generated.
I have used the Array.Copy() method over the use of StringBuilder, as a copying of the content of the StringBuilder into itself would have the overhead of producing a new string with that content with each iteration. Array.Copy() avoids this, while still operating with an extremely high rate of efficiency.
This solution takes O(1 + log N) iterations to complete, a rate that increases logarithmically with the number of repeats (doubling the number of repeats equals one additional iteration), a substantial savings over the other methods, which increase proportionally.