The problem is in function which you choose. Factorial is a function which grows very fast. Erlang has implemented big integer arithmetics, so it will not overflow. You are effectively measuring how good is underlying big integer implementation. 1000000! is a huge number. It is 8.26×10^5565708 which is like 5.6MB long written as a decadic number. There is a difference between your `fac/1`

and `tail_fac/1`

how fast they reach big numbers where big integer implementation kicks in and how fast the number grows. In you `fac/1`

implementation you are effectively computing `1*2*3*4*...*N`

. In your `tail_fac/1`

implementation you are computing `N*(N-1)*(N-2)*(N-3)*...*1`

. Do you see the issue there? You can write tail call implementation in a different way:

```
tail_fac2(N) when is_integer(N), N > 0 ->
tail_fac2(N, 0, 1).
tail_fac2(X, X, Acc) -> Acc;
tail_fac2(N, X, Acc) ->
Y = X + 1,
tail_fac2(N, Y, Y*Acc).
```

It will work much better. I'm not patient as you are so I will measure a little bit smaller numbers but the new `fact:tail_fac2/1`

shoudl outperform `fact:fac/1`

every single time:

```
1> element(1, timer:tc(fun()-> fact:fac(100000) end)).
7743768
2> element(1, timer:tc(fun()-> fact:fac(100000) end)).
7629604
3> element(1, timer:tc(fun()-> fact:fac(100000) end)).
7651739
4> element(1, timer:tc(fun()-> fact:tail_fac(100000) end)).
7229662
5> element(1, timer:tc(fun()-> fact:tail_fac(100000) end)).
7104056
6> element(1, timer:tc(fun()-> fact:tail_fac2(100000) end)).
6491195
7> element(1, timer:tc(fun()-> fact:tail_fac2(100000) end)).
6506565
8> element(1, timer:tc(fun()-> fact:tail_fac2(100000) end)).
6519624
```

As you can see `fact:tail_fac2/1`

for `N = 100000`

takes 6.5s, `fact:tail_fac/1`

takes 7.2s and `fact:fac/1`

takes 7.6s. Even faster growth doesn't overturn tail call benefit so tail call version is faster than body recursive one there is clearly seen that slower growth of accumulator in `fact:tail_fac2/1`

show its impact.

If you choose a different function for tail call optimization testing you can see the impact of tail call optimization more clearly. For example sum:

```
sum(0) -> 0;
sum(N) when N > 0 -> N + sum(N-1).
tail_sum(N) when is_integer(N), N >= 0 ->
tail_sum(N, 0).
tail_sum(0, Acc) -> Acc;
tail_sum(N, Acc) -> tail_sum(N-1, N+Acc).
```

And speed is:

```
1> element(1, timer:tc(fun()-> fact:sum(10000000) end)).
970749
2> element(1, timer:tc(fun()-> fact:sum(10000000) end)).
126288
3> element(1, timer:tc(fun()-> fact:sum(10000000) end)).
113115
4> element(1, timer:tc(fun()-> fact:sum(10000000) end)).
104371
5> element(1, timer:tc(fun()-> fact:sum(10000000) end)).
125857
6> element(1, timer:tc(fun()-> fact:tail_sum(10000000) end)).
92282
7> element(1, timer:tc(fun()-> fact:tail_sum(10000000) end)).
92634
8> element(1, timer:tc(fun()-> fact:tail_sum(10000000) end)).
68047
9> element(1, timer:tc(fun()-> fact:tail_sum(10000000) end)).
87748
10> element(1, timer:tc(fun()-> fact:tail_sum(10000000) end)).
94233
```

As you can see, there we can easily use `N=10000000`

and it works pretty fast. Anyway, body recursive function is significantly slower 110ms vs 85ms. You can notice the first run of `fact:sum/1`

took 9x longer than the rest of runs. It is because of body recursive function consuming a stack. You will not see such effect when you use a tail recursive counterpart. (Try it.) You can see the difference if you run each measurement in a separate process.

```
1> F = fun(G, N) -> spawn(fun() -> {T, _} = timer:tc(fun()-> fact:G(N) end), io:format("~p took ~bus and ~p heap~n", [G, T, element(2, erlang:process_info(self(), heap_size))]) end) end.
#Fun<erl_eval.13.91303403>
2> F(tail_sum, 10000000).
<0.88.0>
tail_sum took 70065us and 987 heap
3> F(tail_sum, 10000000).
<0.90.0>
tail_sum took 65346us and 987 heap
4> F(tail_sum, 10000000).
<0.92.0>
tail_sum took 65628us and 987 heap
5> F(tail_sum, 10000000).
<0.94.0>
tail_sum took 69384us and 987 heap
6> F(tail_sum, 10000000).
<0.96.0>
tail_sum took 68606us and 987 heap
7> F(sum, 10000000).
<0.98.0>
sum took 954783us and 22177879 heap
8> F(sum, 10000000).
<0.100.0>
sum took 931335us and 22177879 heap
9> F(sum, 10000000).
<0.102.0>
sum took 934536us and 22177879 heap
10> F(sum, 10000000).
<0.104.0>
sum took 945380us and 22177879 heap
11> F(sum, 10000000).
<0.106.0>
sum took 921855us and 22177879 heap
```