Great question.

This multithreaded implementation of the Fibonacci function is *not* faster than the single threaded version. That function was only shown in the blog post as a toy example of how the new threading capabilities work, highlighting that it allows for spawning many many threads in different functions and the scheduler will figure out an optimal workload.

The problem is that `@spawn`

has a non-trivial overhead of around `1µs`

, so if you spawn a thread to do a task that takes less than `1µs`

, you've probably hurt your performance. The recursive definition of `fib(n)`

has exponential time complexity of order `1.6180^n`

[1], so when you call `fib(43)`

, you spawn something of order `1.6180^43`

threads. If each one takes `1µs`

to spawn, it'll take around 16 minutes just to spawn and schedule the needed threads, and that doesn't even account for the time it takes to do the actual computations and re-merge / sync threads which takes even more time.

Things like this where you spawn a thread for each step of a computation only make sense if each step of the computation takes a long time compared to the `@spawn`

overhead.

Note that there is work going into lessening the overhead of `@spawn`

, but by the very physics of multicore silicon chips I doubt it can ever be fast enough for the above `fib`

implementation.

If you're curious about how we could modify the threaded `fib`

function to actually be beneficial, the easiest thing to do would be to only spawn a `fib`

thread if we think it will take significantly longer than `1µs`

to run. On my machine (running on 16 physical cores), I get

```
function F(n)
if n < 2
return n
else
return F(n-1)+F(n-2)
end
end
julia> @btime F(23);
122.920 μs (0 allocations: 0 bytes)
```

so thats a good two orders of magnitude over the cost of spawning a thread. That seems like a good cutoff to use:

```
function fib(n::Int)
if n < 2
return n
elseif n > 23
t = @spawn fib(n - 2)
return fib(n - 1) + fetch(t)
else
return fib(n-1) + fib(n-2)
end
end
```

now, if I follow proper benchmark methodology with BenchmarkTools.jl [2] I find

```
julia> using BenchmarkTools
julia> @btime fib(43)
971.842 ms (1496518 allocations: 33.64 MiB)
433494437
julia> @btime F(43)
1.866 s (0 allocations: 0 bytes)
433494437
```

@Anush asks in the comments: This is a factor of 2 speed up using 16 cores it seems. Is it possible to get something closer to a factor of 16 speed up?

Yes it is. The problem with the above function is that the function body is larger than that of `F`

, with lots of conditionals, function / thread spawning and all that. I invite you to compare `@code_llvm F(10)`

`@code_llvm fib(10)`

. This means that `fib`

is much harder for julia to optimize. This extra overhead it makes a world of difference for the small `n`

cases.

```
julia> @btime F(20);
28.844 μs (0 allocations: 0 bytes)
julia> @btime fib(20);
242.208 μs (20 allocations: 320 bytes)
```

Oh no! all that extra code that never gets touched for `n < 23`

is slowing us down by an order of magnitude! There's an easy fix though: when `n < 23`

, don't recurse down to `fib`

, instead call the single threaded `F`

.

```
function fib(n::Int)
if n > 23
t = @spawn fib(n - 2)
return fib(n - 1) + fetch(t)
else
return F(n)
end
end
julia> @btime fib(43)
138.876 ms (185594 allocations: 13.64 MiB)
433494437
```

which gives a result closer to what we'd expect for so many threads.

[1] https://www.geeksforgeeks.org/time-complexity-recursive-fibonacci-program/

[2] The BenchmarkTools `@btime`

macro from BenchmarkTools.jl will run functions multiple times, skipping the compilation time and average results.