I've mentioned C++ template metaprogramming in my comment above. Let me therefore provide a brief example using C++ template meta-programming. I'm aware that you tagged your question with `java`

, yet this may be insightful. I hope you will be able to understand the C++ code.

## Demonstration by example:

Consider the following recursive function, which generates the Fibonacci series (0, 1, 1, 2, 3, 5, 8, 13, ...):

```
unsigned int fib(unsigned int n)
{
return n >= 2 ? fib(n-2) + fib(n-1) : n;
}
```

To get an item from the Fibonacci series, you call this function -- e.g. `fib(5)`

--, and it will compute the value and return it to you. Nothing special so far.

But now, in C++ you can re-write this code using templates (somewhat similar to generics in Java) so that the Fibonacci series won't be generated at *run-time*, but during *compile-time*:

```
// fib(n) := fib(n-2) + fib(n-1)
template <unsigned int n>
struct fib // <-- this is the generic version fib<n>
{
static const unsigned int value = fib<n-2>::value + fib<n-1>::value;
};
// fib(0) := 0
template <>
struct fib<0> // <-- this overrides the generic fib<n> for n = 0
{
static const unsigned int value = 0;
};
// fib(1) := 1
template <>
struct fib<1> // <-- this overrides the generic fib<n> for n = 1
{
static const unsigned int value = 1;
};
```

To get an item from the Fibonacci series using this template, simply retrieve the constant value -- e.g. `fib<5>::value`

.

## Conclusion ("What does this have to do with meta-programming?"):

In the template example, **it is the C++ compiler that generates the Fibonacci series at compile-time, not your program while it runs.** (This is obvious from the fact that in the first example, you call a function, while in the template example, you retrieve a constant value.) You get your Fibonacci numbers without writing a function that computes them! Instead of programming that function, you have programmed the compiler to do something for you that it wasn't explicitly designed for... which is quite remarkable.

This is therefore one form of meta-programming:

*Metaprogramming is the writing of computer programs that write or manipulate other programs (or themselves) as their data, ***or that do part of the work at compile time that
would otherwise be done at runtime**.

-- Definition from the Wikipedia article on metaprogramming, emphasis added by me.

(Note also the side-effects in the above template example: As you make the compiler pre-compute your Fibonacci numbers, they need to be stored somewhere. The size of your program's binary will increase proportionally to the highest `n`

that's used in expressions containing the term `fib<n>::value`

. On the upside, you save computation time at run-time.)