Following the approach of this answer I am trying to understand what happens exactly and how expressions and generated functions work in Julia within the concept of metaprogramming.

The goal is to optimize a recursive function using expressions and generated functions (for a concrete example you can have a look at the question answered in the link provided above).

Consider the following modified fibonacci function, in which I want to compute the fibonacci series up to `n`

and multiply it by a number `p`

.

The straightforward, recursive implementation would be

```
function fib(n::Integer, p::Real)
if n <= 1
return 1 * p
else
return n * fib(n-1, p)
end
end
```

As a first step, I could define a function which returns an *expression* instead of the computed value

```
function fib_expr(n::Integer, p::Symbol)
if n <= 1
return :(1 * $p)
else
return :($n * $(fib_expr(n-1, p)))
end
end
```

which, e.g. returns something like

```
julia> ex = fib_expr(3, :myp)
:(3 * (2 * (1myp)))
```

In this way I get an expression which is *fully expanded* and depends on the value assigned to the symbol `myp`

. In this way I do not see the recursion anymore, basically I am *metaprogramming*: I created a function that creates another "function" (in this case we call it expression though).
I can now set `myp = 0.5`

and call `eval(ex)`

to compute the result.
However, this is **slower** than the first approach.

What I can do though, is to generate a parametric function in the following way

```
@generated function fib_gen{n}(::Type{Val{n}}, p::Real)
return fib_expr(n, :p)
end
```

And magically, calling `fib_gen(Val{3}, 0.5)`

gets things done, and is incredibly fast.

**So, what is going on?**

To my understanding, in the first call to `fib_gen(Val{3}, 0.5)`

, the parametric function `fib_gen{Val{3}}(...)`

gets compiled and its content is the fully expanded expression obtained through `fib_expr(3, :p)`

, i.e. `3*2*1*p`

with `p`

substituted with the input value.
The reason why it is so fast then, is because `fib_gen`

is basically just a series of multiplications, whereas the original `fib`

has to allocate on the stack every single recursive call making it slower, **am I correct?**

To give some numbers, here is my short benchmark `using BenchmarkTools`

.

```
julia> @benchmark fib(10, 0.5)
...
mean time: 26.373 ns
...
julia> p = 0.5
0.5
julia> @benchmark eval(fib_expr(10, :p))
...
mean time: 177.906 μs
...
julia> @benchmark fib_gen(Val{10}, 0.5)
...
mean time: 2.046 ns
...
```

I have many questions:

- Why the second case is so slow?
- What exactly is and means
`::Type{Val{n}}`

? (I copied that from the answer linked above) - Because of the JIT compiler, sometimes I am lost in what happens at
*compile-time*and at*run-time*, as it is the case here...

Furthermore, I tried to combine `fib_expr`

and `fib_gen`

in a single function according to

```
@generated function fib_tot{n}(::Type{Val{n}}, p::Real)
if n <= 1
return :(1 * p)
else
return :(n * fib_tot(Val{n-1}, p))
end
end
```

which however is slow

```
julia> @benchmark fib_tot(Val{10}, 0.5)
...
mean time: 4.601 μs
...
```

What am I doing wrong here? Is it even possible to combine `fib_expr`

and `fib_gen`

in a single function?

I realize this is more a monograph rather than a question, however, even though I read the metaprogramming section few times, I am having a hard time to grasp everything, in particular with an applied example such as this one.

exactlythe same in practice, however for understanding the concept I believe it considers all points touched in my other question. On top of that, in principle, from what I understood so far,`fib_gen`

is actually going to be always faster than`fib`

as long as generating the expression(s) does not provoke a`StackOverflowError`

. – Batta Jul 6 '18 at 12:32muchslower than one call of just`fib`

. It depends on your use case whether it pays off, and for Fibonacci numers, it probably won't often. That's what I meant to say. – phg Jul 6 '18 at 12:35or from the outside. If you do it inside, you have to understand what the language/compiler offers and its strengths and limitations, often many. If you do from outside, a) there are no limitations due the language or compiler, b) the concepts are often cleaner because they have to be general. See my Software Engineering answer on metaprogramming: softwareengineering.stackexchange.com/a/257441/12135 – Ira Baxter Jul 6 '18 at 16:39