# Short answer

If the **number of ***possible characters* (not to be confused with the *length of the strings*) is not fixed (not the case here) the time complexity of your algorithm is **O(n^2)**. **If we make the assumption there are only a fixed number of valid characters** (in this case `255`

/`4G`

), your algorithm runs in worst-case *O(n)*. If the **condition holds**, the algorithm can then easily be **improved to run in ***O(1)*.

**Note on asymptotic behavior and big-oh**: these are *theoretical* results. It's not because an algorithm runs in *O(1)*, it runs in *reasonable time*. It means it runs in constant time. So that - asymptotically speaking - it won't make any difference whether you enter a string with length 10^{1000} or one with length 10^{10'000} (given these lengths are large enough). The time it takes can be more than one hundred times the age of the universe as well.

# Explanation

You can do a simple **more than worst-case** analysis on the for loops:

```
for (; *scout != '\0'; ++scout, ++offset)
for (start = (char *)str + offset; *start != '\0'; ++start)
//single statement
```

Now we want to know how many times the single statement (it contains a fixed number of statements) will be repeated. Since you never **modify** the content of the string. We know that there is an index *n* at which the value is `\0`

.

So we can rewrite it as:

```
for (scout = 0,offset = 0; scout < n; ++scout, ++offset)
for (start = offset; *start < n; ++start)
//single statement
```

(I've assumed the string starts at memory address `0`

), but since that's only a shift, that allowed, it makes it only simpler to reason about this.

Now we're going to calculate the number of statements in the inner `for`

loop (parameterized). That's equal to:

With *o* the offset and *n* the length of the string.

Now we can use this formula to calculate the number of instructions at the outer `for`

-loop level. Here *o* starts with `0`

and iterates through (excluding) `n`

. So the total number of instructions is:

Which is *O(n^2)*.

But now one has to ask: **is it possible to construct such a string**? The answer is **no**! There are only `255`

valid characters (the `NUL`

character is not considered to be a character); if we cannot make this assumption the above holds. Say the first character is an `a`

(with a an arbitrary char), then it either matches with another `a`

in the string, which can be resolved in *O(n)* time (loop through the remainder of the string); or it means that all other characters are **different from **`a`

. In the first case, the algorithm terminates in O(n); in the second case, this means that the second character is different.

Let's say the second character is `b`

. Then we again iterate over the string in *O(n)* and if it finds another `b`

we terminate, after *2n* or *O(n)* steps. If not, we need try to find a match for the next character `c`

.

The point is that we only need to do this **at most **`255`

times: because **there are only 255 valid characters**. As a result the time complexity is *255n* or *O(n)*.

## Alternative explanation

Another variant of this explanation is *"if the outer *`for`

loop is looking for the i-th character we know that all characters on the left of i, are different from that character (otherwise we would have already rejected earlier)." Now since there are only `255`

characters and all characters on the left are different from each other and the current character, we know that for the `256`

-th character of the string, we cannot find a new different character anymore, because there are no such characters.

## Example

Say you have an alphabet with `3`

characters (`a`

,`b`

and `c`

) - this only to make it easier to understand the matter. Now say we have a string:

```
scout
v
b a a a a a b
^
start
```

It is clear that your algorithm will use *O(n)* steps: the `start`

will simply iterate over the entire string once, reach `b`

and return.

Now say there is no duplicate of `b`

in the string. In that case the algorithm does not stop after iterating over the string once. But this implies all the other characters should differ from *a* (after all we've iterated over the string, and didn't find a duplicate). So now consider a string with that condition:

```
scout
v
b a a a a a a
^
start
```

Now it is clear that a first attempt to find a character `b`

in the remainder of the string will fail. Now your algorithm increments the scout:

```
scout
v
b a a a a a a
^
start
```

And starts searching for `a`

. Here we're very lucky: the first character is an `a`

. But if there is a duplicate `a`

; it would cost at most two iterations, so *O(2n)* to find the duplicate.

Now we're reaching the bound case: there is no `a`

either. In that case, we know the string must begin with

```
scout
v
b a c ...
```

We furthermore know that the remainder of the string cannot contain `b`

's nor `a`

's because otherwise the `scout`

would never have moved that far. The only remaining possibility is that the remainder of the string contains `c`

's. So the string reads:

```
scout
v
b a c c c c c c c c c c
^
start
```

This means that after **iterating over the string at most 3 times**, we will find such duplicate, regardless of the size of the string, or how the characters are distributed among that string.

# Modify this to *O(1)* time

You can easily modify this algorithm to let it run in O(1) time: simply place additional bounds on the indices:

```
int strunique(const char *str)
{
size_t offset = 1;
char *scout = (char *)str, *start, *stop = scout+255;
for (; scout < stop && *scout != '\0'; ++scout, ++offset)
for (start = (char *)str + offset; start <= stop && *start != '\0'; ++start)
if (*start == *scout)
return 0;
return 1;
}
```

In this case we've bounded the first loop such that it visits **at most the first 255** characters, the inner loop visits only the first **256** (notice the `<=`

instead of `<`

). So the total number of steps is bounded by *255 x 256* or *O(1)*. The explanation above already demonstrates why this is sufficient.

**Note**: In case this is `C`

, you need to replace `255`

by `4'294'967'296`

which makes it indeed theoretically *O(n)*, but practically *O(n^2)* in the sense that the constant factor before the *n* is that huge for *O(n)* that *O(n^2)* will outperform it.

Since we combine the string termination check with the `256`

-check this algorithm will run nearly always faster than the one proposed above. The only source of potentially extra cycles is the additional testing that ships with the modified `for`

-loops. But since these lead to faster termination, it will in many cases not result in additional time.

# Big-oh

One can say: "*Yes that's true for strings with length greater than or equal to 256 characters.*", "What about strings with a size less than `256`

?". The point is that **big-oh analysis deals with asymptotic behavior**. Even if the behavior was super-exponential for some strings less than or equal to a certain length, you don't take these into account.

To emphasize the (problematic) aspect of *asymptotic* behavior more. One can say that the following algorithm would be correct asymptotically speaking:

```
int strunique(const char *str) {
return 0;
}
```

It always returns false; because *"There is a length n*_{0} such that for every input length n > n_{0} this algorithm will return the correct result." This has not much to do with big-oh itself, it's more to illustrate that one must be careful with saying an algorithm running in *O(1)* will outperform an algorithm in *O(n^6)* for any reasonable input. Sometimes the constant factor can be gigantic.

`char`

replaced by`std::string`

, or worse,`Foobar`

. – jxh May 21 '15 at 2:20