I'm working on a project for which I need a very fast algorithm for checking whether a supplied number is pandigital. Though the logic seems sound, I'm not particularly happy with performance of the methods described below.

I can check up to one million 9-digit numbers in about 520ms, 600ms and 1600ms respectively. I'm working on a low-latency application and in production I'll have a dataset of about 9 or 9.5 billion 7- to 9-digit numbers that I'll need to check.

I have three candidiates right now (well, really two) that use the following logic:

**Method 1:** I take an input `N`

, split into into a byte array of its constituent digits, sort it using an `Array.Sort`

function and iterate over the array using a `for`

loop checking for element vs counter consistency:

```
byte[] Digits = SplitDigits(N);
int len = NumberLength(N);
Array.Sort(Digits);
for (int i = 0; i <= len - 1; i++)
{
if (i + 1 != Digits[i])
return false;
}
```

**Method 2:** This method is based on a bit of dubious logic, but I split the input `N`

into a byte array of constituent digits and then make the following test:

```
if (N * (N + 1) * 0.5 == DigitSum(N) && Factorial(len) == DigitProduct(N))
return true;
```

**Method 3:** I dislike this method, so not a real candidate but I cast the int to a string and then use `String.Contains`

to determine if the required string is pandigital.

The second and third method have fairly stable runtimes, though the first method bounces around a lot - it can go as high as 620ms at times.

So ideally I really like to reduce the runtime for the million 9-digit mark to under 10ms. Any thoughts?

I'm running this on a Pentium 6100 laptop at 2GHz.

PS - is the mathematical logic of the second method sound?

andFactorial(N). I would have thought this method is valid? – insomniac Mar 3 '13 at 18:55