**On speed:**

As already pointed out in the comments, the primary goal of tail-call-optimization is to reduce the usage of the stack.

However, often there is a collateral: the program becomes faster because there is no overhead needed for a call of a function. This gain is most prominent if the work in the function itself is not that big, so the overhead has some weight.

If there is a lot of work done during a function call, the overhead can be neglected and there is no noticeable speed-up.

On the other hand, if tail call optimization is done, that means that potentially other optimization cannot be done, which could otherwise speed-up your code.

The case of your quick-sort is not that clear cut: There are some calls with a lot of workload and a lot of calls with a very small work load.

So, for 1M elements there are more disadvantages from tail-call-optimization as advantages. On my machine the tail-call-optimized function becomes faster than the non-optimized function for arrays smaller than `50000`

elements.

I must confess, I cannot say, why this is the case alone from looking at the assembly. All I can understand, is that the resulting assemblies are pretty different and that the `quicksort`

is really called once for the optimized version.

There is a clear cut example, for which tail-call-optimization is much faster (because there is not very much happening in the function itself and the overhead is noticeable):

```
//fib.cpp
#include <iostream>
unsigned long long int fib(unsigned long long int n){
if (n==0 || n==1)
return 1;
return fib(n-1)+fib(n-2);
}
int main(){
unsigned long long int N;
std::cin >> N;
std::cout << fib(N);
}
```

running `time echo "40" | ./fib`

, I get `1.1`

vs. `1.6`

seconds for tail-call-optimized version vs. non-optimized version. Actually, I'm pretty impressed, that the compiler is able to use tail-call-optimization here - but it really does, as can be see at godbolt.org, - the second call of `fib`

is optimized.

**On tail call optimization:**

Usually, tail-call optimization can be done if the recursion call is the last operation (prior to `return`

) in the function - the variables on the stack can be reused for the next call, i.e. the function should be of the form

```
ResType f( InputType input){
//do work
InputType new_input = ...;
return f(new_input);
}
```

There are some languages which don't do tail call optimization at all (e.g. python) and some for which you can explicitely ask the compiler to do it and the compiler will fail if it were not able to (e.g. clojure). c++ goes a way in beetween: the compiler tries its best (which is amazingly good!), but you have no guarantee it will succseed and if not, it silently falls to a version without tail-call-optimization.

Let's take look at this simple and standard implementation of tail call recursion:

```
//should be called fac(n,1)
unsigned long long int
fac(unsigned long long int n, unsigned long long int res_so_far){
if (n==0)
return res_so_far;
return fac(n-1, res_so_far*n);
}
```

This classical form of tail-call makes it easy for compiler to optimize: see result here - no recursive call to `fac`

!

However, the gcc compiler is able to perform the TCO also for less obvious cases:

```
unsigned long long int
fac(unsigned long long int n){
if (n==0)
return 1;
return n*fac(n-1);
}
```

It is easier to read and write for us humans, but harder to optimize for compiler (fun fact: TCO is not performed if the return type would be `int`

instead of `unsigned long long int`

): after all the result from the recursive call is used for further calculations (multiplication) before it is returned. But gcc manages to perform TCO here as well!

At hand of this example, we can see the result of TCO at work:

```
//factorial.cpp
#include <iostream>
unsigned long long int
fac(unsigned long long int n){
if (n==0)
return 1;
return n*fac(n-1);
}
int main(){
unsigned long long int N;
std::cin >> N;
std::cout << fac(N);
}
```

Running `time echo "40000000" | ./factorial`

will get you the result (0) in no time if the tail-call-optimization was on, or "Segmentation fault" otherwise - because of the stack-overflow due to recursion depth.

Actually it is a simple test to see whether the tail-call-optimization was performed or not: "Segmentation fault" for non-optimized version and large recursion depth.

**Corollary:**

As already pointed out in the comments: Only the second call of the `quick-sort`

is optimized via TLO. In you implementation, if you are unlucky and the second half of the array always consist of only one element you will need `O(n)`

space on the stack.

However, if the first call would be always with the smaller half and the second call with the larger half were TLO, you would need at most `O(log n)`

recursion depth and thus only `O(log n)`

space on the stack.

That means you should check for which part of the array you call the `quicksort`

first as it plays a huge role.

recursingon the shorter partition and thenloopingon the longer one, you guarantee that the recursion depth is less than the log2 of the number of elements, which can be considered a small constant on most practical hardware. (eg. much smaller than 64) – rici Oct 18 '17 at 15:57