I heard that being conscious of type-stability contributes a lot to the high performance in Julia programming, so I tried to measure how much time I can save when rewriting the type-unstable function into type-stable version. As many people say, I assumed that type-stable coding of course has higher performance than type-unstable one. However, the result was otherwise:

```
# type-unstable vs type-stable
# type-unstable
function positive(x)
if x < 0
return 0.0
else
return x
end
end
# type-stable
function positive_safe(x)
if x < 0
return zero(x)
else
return x
end
end
@time for n in 1:100_000_000
a = 2^( positive(-n) + 1 )
end
@time for n in 1:100_000_000
b = 2^( positive_safe(-n) + 1 )
end
```

result:

```
0.040080 seconds
0.150596 seconds
```

I cannot believe this. Are there some mistakes in my code? Or this is the fact?

Any information would be appreciated.

## Context

- Operating System and version: Windows 10
- Browser and version: Google Chrome 90.0.4430.212（Official Build） （64 bit)
- JupyterLab version: 3.0.14

## @btime result

### Just replacing @time with @btime for my code above

```
@btime for n in 1:100_000_000
a = 2^( positive(-n) + 1 )
end
# -> 1.500 ns
@btime for n in 1:100_000_000
b = 2^( positive_safe(-n) + 1 )
end
# -> 503.146 ms
```

Still weird.

### the exact same code DNF showed me

```
using BenchmarkTools
@btime 2^(positive(-n) + 1) setup=(n=rand(1:10^8))
# -> 32.435 ns (0 allocations: 0 bytes)
@btime 2^(positive_safe(-n) + 1) setup=(n=rand(1:10^8))
#-> 3.103 ns (0 allocations: 0 bytes)
```

Works as expected.

I still don't understand what is happening.
I feel like I have to know better about the usage of `@btime`

and benchmarking process.

By the way, as I said above, I'm trying this benchmarking on Jupyterlab.