The recursive function is a function which **calls by itself**

It allows programmers to write efficient programs using a **minimal amount of code**.

The downside is that they can **cause infinite loops** and other unexpected results if **not written properly**.

I will explain both **Simple Recursive function and Tail Recursive function**

In order to write a **Simple recursive function**

**The first point to consider is when should you decide on coming out
of the loop which is the if loop**
**The second is what process to do if we are our own function**

From the given example:

```
public static int fact(int n){
if(n <=1)
return 1;
else
return n * fact(n-1);
}
```

From the above example

```
if(n <=1)
return 1;
```

Is the deciding factor when to exit the loop

```
else
return n * fact(n-1);
```

Is the actual processing to be done

Let me the break the task one by one for easy understanding.

Let us see what happens internally if I run `fact(4)`

**Substituting n=4**

```
public static int fact(4){
if(4 <=1)
return 1;
else
return 4 * fact(4-1);
}
```

`If`

loop fails so it goes to `else`

loop
so it returns `4 * fact(3)`

In stack memory, we have `4 * fact(3)`

**Substituting n=3**

```
public static int fact(3){
if(3 <=1)
return 1;
else
return 3 * fact(3-1);
}
```

`If`

loop fails so it goes to `else`

loop

so it returns `3 * fact(2)`

Remember we called ```4 * fact(3)``

The output for `fact(3) = 3 * fact(2)`

So far the stack has `4 * fact(3) = 4 * 3 * fact(2)`

In stack memory, we have `4 * 3 * fact(2)`

**Substituting n=2**

```
public static int fact(2){
if(2 <=1)
return 1;
else
return 2 * fact(2-1);
}
```

`If`

loop fails so it goes to `else`

loop

so it returns `2 * fact(1)`

Remember we called `4 * 3 * fact(2)`

The output for `fact(2) = 2 * fact(1)`

So far the stack has `4 * 3 * fact(2) = 4 * 3 * 2 * fact(1)`

In stack memory, we have `4 * 3 * 2 * fact(1)`

**Substituting n=1**

```
public static int fact(1){
if(1 <=1)
return 1;
else
return 1 * fact(1-1);
}
```

`If`

loop is true

so it returns `1`

Remember we called `4 * 3 * 2 * fact(1)`

The output for `fact(1) = 1`

So far the stack has `4 * 3 * 2 * fact(1) = 4 * 3 * 2 * 1`

Finally, the result of **fact(4) = 4 * 3 * 2 * 1 = 24**

The **Tail Recursion** would be

```
public static int fact(x, running_total=1) {
if (x==1) {
return running_total;
} else {
return fact(x-1, running_total*x);
}
}
```

**Substituting n=4**

```
public static int fact(4, running_total=1) {
if (x==1) {
return running_total;
} else {
return fact(4-1, running_total*4);
}
}
```

`If`

loop fails so it goes to `else`

loop
so it returns `fact(3, 4)`

In stack memory, we have `fact(3, 4)`

**Substituting n=3**

```
public static int fact(3, running_total=4) {
if (x==1) {
return running_total;
} else {
return fact(3-1, 4*3);
}
}
```

`If`

loop fails so it goes to `else`

loop

so it returns `fact(2, 12)`

In stack memory, we have `fact(2, 12)`

**Substituting n=2**

```
public static int fact(2, running_total=12) {
if (x==1) {
return running_total;
} else {
return fact(2-1, 12*2);
}
}
```

`If`

loop fails so it goes to `else`

loop

so it returns `fact(1, 24)`

In stack memory, we have `fact(1, 24)`

**Substituting n=1**

```
public static int fact(1, running_total=24) {
if (x==1) {
return running_total;
} else {
return fact(1-1, 24*1);
}
}
```

`If`

loop is true

so it returns `running_total`

The output for `running_total = 24`

Finally, the result of **fact(4,1) = 24**

is"normal" recursion. It only means that the recursion occurs at the end of the function.`-O3`

. The link is for an earlier discussion that covers very similar ground and discusses what is necessary to implement this optimization.5more comments