While several people point out the perfect-square solution, it involves squaring a Fibonacci number, frequently resulting in a **massive** product.

There are less than 80 Fibonacci numbers that can even be held in a standard 64-bit integer.

Here is my solution, which operates entirely *smaller* than the number to be tested.

(written in C#, using basic types like `double`

and `long`

. But the algorithm should work fine for bigger types.)

```
static bool IsFib(long T, out long idx)
{
double root5 = Math.Sqrt(5);
double phi = (1 + root5) / 2;
idx = (long)Math.Floor( Math.Log(T*root5) / Math.Log(phi) + 0.5 );
long u = (long)Math.Floor( Math.Pow(phi, idx)/root5 + 0.5);
return (u == T);
}
```

More than 4 years after I wrote this answer, a commenter asked about the second parameter, passed by

`out`

.

Parameter #2 is the "Index" into the Fibonacci sequence.

If the value to be tested, `T`

is a Fibonacci number, then `idx`

will be the 1-based index of that number in the Fibonacci sequence. (with one notable exception)

The Fibonacci sequence is `1 1 2 3 5 8 13`

, etc.

3 is the 4th number in the sequence: `IsFib(3, out idx);`

will return `true`

and value `4`

.

8 is the 6th number in the sequence: `IsFib(8, out idx);`

will return `true`

and value `6`

.

13 is the 7th number; `IsFib(13, out idx);`

will return `true`

and value `7`

.

The one exception is `IsFib(1, out idx);`

, which will return `2`

, even though the value 1 appears at both index 1 and 2.

If `IsFib`

is passed a non-Fibonacci number, it will return `false`

, and the value of `idx`

will be the index of the biggest Fibonacci number less than `T`

.

16 is not a Fibonacci value.

`IsFib(16, out idx);`

will return `false`

and value `7`

.

You can use Binet's Formula to convert index 7 into Fibonacci value 13, which is the largest number less than 16.