A much more tidy and elegant solution (which I've called **Basic Solution**) is as follows:

**Basic Solution**

```
char *internalRepeat(char *s, int n, size_t total)
{
return (n > 0)
? strcat(internalRepeat(s, n - 1, total + strlen(s)), s)
: strcpy(malloc(total + 1), "");
}
char *repeat(char *s, int n)
{
return internalRepeat(s, n, 0);
}
```

This is the beauty of recursion. The key to this solution uses recursion to incrementally build the length of the result. Parameter `total`

does this (not including the NUL-terminator). When the recursion terminates, the result buffer is allocated once (including the NUL-terminator) and then we use the recursion unwinding to append each copy of `s`

to the result. Basic Solution behaves as follows:

- Returns a zero-length string for any number of repetitions of an
empty string.
- Returns a zero-length string for zero or negative iterations of a non-empty
string.
- Returns a non-zero-length string for a non-zero-positive number of
repetitions on a non-empty string.

If you create a program based on the above functions, the following statements:

```
printf("Repeat \"\" 0 times: [%s]\n", repeat("", 0));
printf("Repeat \"\" 3 times: [%s]\n", repeat("", 3));
printf("Repeat \"abcde\" 0 times: [%s]\n", repeat("abcde", 0));
printf("Repeat \"abcde\" 1 times: [%s]\n", repeat("abcde", 1));
printf("Repeat \"abcde\" 4 times: [%s]\n", repeat("abcde", 4));
```

will produce the following output:

```
Repeat "" 0 times: []
Repeat "" 3 times: []
Repeat "abcde" 0 times: []
Repeat "abcde" 1 times: [abcde]
Repeat "abcde" 4 times: [abcdeabcdeabcdeabcde]
```

**EDIT : Optimised Solution follows. Read on if you're interested in optimisation techniques.**

All the other proposals here principally run in **O(***n^2*) and allocate memory at every iteration. Even though Basic Solution is elegant, uses only a single `malloc()`

, and takes only two statements, surprisingly **Basic Solution also has a running time of O(***n^2*). This makes it very inefficient if string `s`

is long and means that Basic Solution is no more efficient than any other proposal here.

**Optimised Solution**

The following is an *optimal* solution to this problem that actually runs in **O(***n*):

```
char *internalRepeat(char *s, int n, size_t total, size_t len)
{
return (n > 0)
? strcpy(internalRepeat(s, n - 1, total, len), s) + len
: strcpy(malloc(total + 1), "");
}
char *repeat(char *s, int n)
{
int len = strlen(s);
return internalRepeat(s, n, n * len, len) - (n * len);
}
```

As you can see, it now has three statements and uses one more parameter, `len`

, to cache the length of `s`

. It recursively uses `len`

to compute the position within the result buffer where the `n`

'th copy of `s`

will be positioned, so allowing us to replace `strcat()`

with `strcpy()`

for each time `s`

is added to the result. This gives an **actual running time** of O(*n*), not O(*n^2*).

**What's the difference between the Basic and Optimised solutions?**

All other solutions have used `strcat()`

at least `n`

times on string `s`

to append `n`

copies of `s`

to the result. This is where the problem lies, because the implementation of `strcat()`

hides an inefficiency. Internally, `strcat()`

can be thought of as:

```
strcat = strlen + strcpy
```

i.e., when appending, you first have to find the end of the string you're appending to *before* you can do the append itself. This hidden overhead means that, in fact, creating `n`

copies of a string requires `n`

length checks and `n`

physical copying operations. However, the real problem lies in that for each copy of `s`

we append, our result gets longer. This means that each successive length check within `strcat()`

on the *result* is also getting longer. If we now compare the two solutions using "*number of times we have to scan or copy *`s`

" as our basis for comparison, we can see where the difference in the two solutions lies.

For `n`

copies of the string `s`

, the Basic Solution performs as follows:

```
strlen's/iteration: 2
strcpy's/iteration: 1
Iteration | Init | 1 | 2 | 3 | 4 | ... | n | Total |
----------+------+---+---+---+---+-----+---+------------+
Scan "s" | 0 | 1 | 2 | 3 | 4 | ... | n | (n+1)(n/2) |
Copy "s" | 0 | 1 | 1 | 1 | 1 | ... | 1 | n |
```

whereas the Optimised Solution performs like this:

```
strlen's/iteration: 0
strcpy's/iteration: 1
Iteration | Init | 1 | 2 | 3 | 4 | ... | n | Total |
----------+------+---+---+---+---+-----+---+------------+
Scan "s" | 1 | 0 | 0 | 0 | 0 | ... | 0 | 1 |
Copy "s" | 0 | 1 | 1 | 1 | 1 | ... | 1 | n |
```

As you can see from the table, the Basic Solution performs (*n^2 + n)/2* scans of our string due to the built-in length check in `strcat()`

, whereas the Optimised Solution always does *(n + 1)* scans. This is why the Basic Solution (and every other solution that relies on `strcat()`

) performs in *O(n^2)*, whereas the Optimised Solution performs in *O(n)*.

**How does O(***n*) compare to O(*n^2*) in real terms?

Running times make a **huge** difference when large strings are being used. As an example, let's take a string `s`

of 1MB that we wish to create 1,000 copies of (== 1GB). If we have a 1GHz CPU that can scan or copy 1 byte/clock cycle, then 1,000 copies of `s`

will be generated as follows:

*Note: ***n** is taken from performance tables above, and represents a single scan of **s**.

```
Basic: (n + 1) * (n / 2) + n = (n ^ 2) / 2 + (3n / 2)
= (10^3 ^ 2) / 2 + (3 * 10^3) / 2
= (5 * 10^5) + (1.5 * 10^2)
= ~(5 * 10^5) (scans of "s")
= ~(5 * 10^5 * 10^6) (bytes scanned/copied)
= ~500 seconds (@1GHz, 8 mins 20 secs).
Optimised: (n + 1) = 10^3 + 1
= ~10^3 (scans of "s")
= ~10^3 * 10^6 (bytes scanned/copied)
= 1 second (@1Ghz)
```

As you can see, the Optimised Solution, which completes nearly instantly, demolishes the Basic Solution which takes nearly 10 minutes to complete. However, if you think making string `s`

smaller will help, this next result will horrify you. Again, on a 1GHz machine that processes 1 byte/clock cycle, we take `s`

as 1KB (1 thousand times smaller), and make 1,000,000 copies (total == 1GB, same as before). This gives:

```
Basic: (n + 1) * (n / 2) + n = (n ^ 2) / 2 + (3n / 2)
= (10^6 ^ 2) / 2 + (3 * 10^6) / 2
= (5 * 10^11) + (1.5 * 10^5)
= ~(5 * 10^11) (scans of "s")
= ~(5 * 10^11 * 10^3) (bytes scanned/copied)
= ~50,000 seconds (@1GHz, 833 mins)
= 13hrs, 53mins, 20 secs
Optimised: (n + 1) = 10^6 + 1
= ~10^6 (scans of "s")
= ~10^6 * 10^3 (bytes scanned/copied)
= 1 second (@1Ghz)
```

This is a truly shocking difference. Optimised Solution performs in the same time as before as the total amount of data written is the same. However, Basic Solution stalls for over **half a day** building the result. This is the difference in running times between O(*n*) and O(*n^2*).