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
        return n * fib(n-1, p)

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 * $p)
        return :($n * $(fib_expr(n-1, p)))

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)

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

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)
        return :(n * fib_tot(Val{n-1}, p))

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.

  • 2
    I like the question, and not only because I triggered it -- very well written. However, using Fibonacci for generated functions is probably not the best example in reality: in your other question, the values for which the methods were generated were bounded beforehand within a small range (by convention), whereas here, you provide the possibility to compile a new one for each single, unbounded value. But it's good enough for understanding the concept, I guess :) – phg Jul 6 '18 at 11:59
  • I agree it is not exactly the 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 12:32
  • If you call it a lot of times, yes. But the first call will be much slower 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 12:35
  • You can metaprogram in the language, or 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

A monograph in response:

Metaprogramming basics

It will be easier to start with "normal" macros first. I'll relax the definition you used a bit:

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

That allows to pass in more than just symbols for p, like integer literals or whole expressions. Given this, we can define a macro for the same functionality:

macro fib_macro(n::Integer, p)
    fib_expr(n, p)

Now, if @fib_macro 45 1 is used anywhere in the code, at compile time it will first be replaced by a long nested expression

:(45 * (44 * ... * (1 * 1)) ... )

and then compiled normally -- to a constant.

That's all there is to macros, really. Replacing syntax during compile time; and by recursion, this can be an arbitrarily long alteration between compiling, and evaluating functions on expressions. And for things that are essentially constant, but tedious to write otherwise, it is very useful: a bood example example is Base.Math.@evalpoly.

Evaluation at runtime?

But it has the problem that you cannot inspect values which are only known at runtime: you can't implement fib(n) = @fib_macro n 1, since at compile time, n is a symbol representing the parameter, and not a number you can dispatch on.

The next best solution to this would be to use

fib_eval(n::Integer) = eval(fib_expr(n, 1))

which works, but will repeat the compilation process every time it is called -- and that is much more overhead than the original function, since now at runtime, we perform the whole recursion on the expression tree and then call the compiler on the result. Not good.

Method dispatch & compilation

So we need a way to intermingle runtime and compile time. Enter @generated functions. These will at runtime dispatch on a type, and then work like a macro defining the function body.

First about type dispatch. If we have

f(x) = x + 1

and have a function call f(1), about the following will happen:

  1. The type of the argument is determined (Int)
  2. The method table of the function is consulted to find the best matching method
  3. The method body is compiled for the specific Int argument type, if that hasn't been done before
  4. The compiled method is evaluated on the concrete argument

If we then enter f(1.0), the same will happen again, with a new, different specialized method being compiled for Float64, based on the same function body.

Value types & singleton types

Now, Julia has the peculiar feature that you can use numbers as types. That means that the dispatch process outlined above will also work on the following function:

g(::Type{Val{N}}) where N = N + 1

That's a bit tricky. Remember that types are themselves values in Julia: Int isa Type.

Here, Val{N} is for every N a so-called singleton type having exactly one instance, namely Val{N}() -- just like Int is a type having many instances 0, -1, 1, -2, ....

Type{T} is also a singleton type, having as its single instance the type T. Int is a Type{Int}, and Val{3} is a Type{Val{3}} -- in fact, both are the only values of their type.

So, for each N, there is a type Val{N}, being the single instance of Type{Val{N}}. Thus, g will be dispatched and compiled for each single N. This is how we can dispatch on numbers as types. This already allows for optimization:

julia> @code_llvm g(Val{1})

define i64 @julia_g_61158(i8**) #0 !dbg !5 {
  ret i64 2

julia> @code_llvm f(1)

define i64 @julia_f_61076(i64) #0 !dbg !5 {
  %1 = shl i64 %0, 2
  %2 = or i64 %1, 3
  %3 = mul i64 %2, %0
  %4 = add i64 %3, 2
  ret i64 %4

But remember that it requires compilation for each new N at the first call.

(And fkt(::T) is just short for fkt(x::T) if you don't use x in the body.)

Integrating generating functions and value types

Finally to generated functions. They work as a slight modification of the above dispatch pattern:

  1. The type of the argument is determined (Int)
  2. The method table of the function is consulted to find the best matching method
  3. The method body is treated as a macro and called with the Int argument type as a parameter, if that hasn't been done before. The resulting expression is compiled into a method.
  4. The compiled method is evaluated on the concrete argument

This pattern allows to change the implementation for each type which the function is dispatched on.

For our concrete setting, we want to dispatch on the Val types representing the arguments of the Fibonacci sequence:

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

You now see that your explanation was exactly right:

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.

I hope that the whole story has also answered all three of your listed questions:

  1. The implementation using eval replicates the recursion every time, plus the overhead of compilation
  2. Val is a trick to lift numbers to types, and Type{T} the singleton type containing only T -- but I hope the examples were helpful enough
  3. Compile time is not before execution, because of JIT -- it is every time a method gets compiled first time, because it get's called.
  • Thank you, this was quite clear. I still have a doubt on Val and Type. You say in the text that Val{N} is a singleton type for N and that Type{T} is a singleton type for T. I don't see why we need Type{Val{N}} if Val{N} is already a singleton. – Batta Jul 7 '18 at 11:50

First of all, I am joining myself to the comments: your question is very well written & constructive.

I have reproduced your results using Julia 0.7-beta.

  • Difference between @generated fib_tot (one piece of code) and fib_gen (that calls fib_expr)

With my julia version results are identicals:

julia> @btime fib_tot(Val{10},0.5)
  0.042 ns (0 allocations: 0 bytes)

julia> @btime fib_gen(Val{10},0.5)
  0.042 ns (0 allocations: 0 bytes)

Sometimes breaking a function into multiple parts see official doc:performance tips can be useful, however in your peculiar case I do not see why this could be useful. At compile time Julia has everything it needs to optimize fib_tot. There is a branch if n<=1 however n is known at "compile time" thanks to the Type{Val{n}} trick and this branch should be removed without problem in the generated (specialized) code.

  • The Type{Val{n}} trick

To specialize functions, Julia inference is performed according to argument type and not according to argument value.

For instance a compiled version of foo(n::Int) = ... is not generated for each n value. You must define a type that depends on n value to reach this goal. This is precisely how Type{Val{n}} works: Val{n} is simply a parametrized empty structure:

struct Val{T} end

Hence, each Val{1}, Val{2}, ... Val{100}, ... is a different type. By consequence, if foo is defined as:

foo(::Type{Val{n}}) where {n} = ...

Each foo(Val{1}), foo(Val{2}), ... foo(Val{100}) will trigger a specialized foo version (because argument type is different).

  • The eval(fib_expr(n, 1)) case


julia> @btime eval(fib_expr(10, :p))
  401.651 μs (99 allocations: 6.45 KiB)

is slow because your expression is (re-)compiled every time. The problem can be avoided if you use a macro instead (see phg answer).

  • The fib version


julia> @btime fib(10,0.5)
  30.778 ns (0 allocations: 0 bytes)

There is only one compiled version of this fib function. By consequence, it must contain all the runtime branch tests etc... This explains how slow it is.

Just a remark about:

  • foo{n}(::Type{Val{n}}) deprecated syntax

The foo{n}(::Type{Val{n}}) syntax is deprecated, the new one is foo(::Type{Val{n}}) where {n}. You can read Julia doc, parametric methods for further details.

My Julia version:

julia> versioninfo()

Julia Version 0.7.0-beta.0
Commit f41b1ecaec (2018-06-24 01:32 UTC)
Platform Info:
  OS: Linux (x86_64-pc-linux-gnu)
  CPU: Intel(R) Xeon(R) CPU E5-2603 v3 @ 1.60GHz
  LIBM: libopenlibm
  LLVM: libLLVM-6.0.0 (ORCJIT, haswell)
  • Thank you, quite useful answer. One comment on the performance of fib_tot: I am using Julia 0.6.3 and in my case fib_tot performs worse than fib_gen as I showed in my post. In particular checking the code with @code_llvm clearly shows the difference. I don't know if this has to do with some optimization of the compiler in 0.7, however it is not due to the flag -O3 when starting Julia, that I tested. – Batta Jul 7 '18 at 12:06
  • Thanks for the feedback. I have no clear explanation concerning this difference v0.6.3 vs v0.7 – Picaud Vincent Jul 7 '18 at 12:35

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