Not understanding how recursive functions work is quite common, but it really indicates that you just don't understand how functions and returning works, because recursive functions work **exactly** the same as ordinary functions.

```
print 4
```

This works because the `print`

statement knows how to print values. It is given the value `4`

, and prints it.

```
print 3 + 1
```

The `print`

statement doesn't understand how to print `3 + 1`

. `3 + 1`

is not a value, it's an expression. Fortunately `print`

doesn't need to know how to print an expression, because it never sees it. Python passes **values** to things, not expressions. So what Python does is *evaluate* the expression when the code is executed. In this case, that results in the value `4`

being produced. Then the value `4`

is given to the `print`

statement, which happily prints it.

```
def f(x):
return x + 1
print f(3)
```

This is very similar to the above. `f(3)`

is an expression, not a value. `print`

can't do anything with it. Python has to evaluate the expression to produce a value to give to print. It does that by going and looking up the name `f`

, which fortunately finds the function object created by the `def`

statement, and calling the function with the argument `3`

.

This results the function's body being executed, with `x`

bound to `3`

. As in the case with `print`

, the `return`

statement can't do anything with the expression `x + 1`

, so Python evaluates that expression to try to find a value. `x + 1`

with `x`

bound to `3`

produces the value `4`

, which is then returned.

Returning a value from a function makes the evaluation of the function-call expression become that value. So, back out in `print f(3)`

, Python has successfully evaluated the expression `f(3)`

to the value `4`

. Which `print`

can then print.

```
def f(x):
return x + 2
def g(y):
return f(y * 2)
print g(1)
```

Here again, `g(2)`

is an expression not a value, so it needs to be evaluated. Evaluating `g(2)`

leads us to `f(y * 2)`

with `y`

bound to `1`

. `y * 2`

isn't a value, so we can't call `f`

on it; we'll have to evaluate that first, which produces the value `2`

. We can then call `f`

on `2`

, which returns `x + 2`

with `x`

bound to `2`

. `x + 2`

evaluates to the value `4`

, which is returned from `f`

and becomes the value of the expression `f(y * 2)`

inside `g`

. This *finally* gives a value for `g`

to return, so the expression `g(1)`

is evaluated to the value `4`

, which is then printed.

Note that when drilling down to evaluate `f(2)`

Python still "remembered" that it was already in the middle of evaluating `g(1)`

, and it comes back to the right place once it knows what `f(2)`

evaluates to.

That's it. That's all there is. You don't need to understand anything special about recursive functions. `return`

makes the expression that called this particular invocation of the function become the value that was given to `return`

. The **immediate** expression, not some higher-level expression that called a function that called a function that called a function. The innermost one. It **doesn't matter** whether the intermediate function-calls happen to be to the same function as this one or not. There's no way for `return`

to even know whether this function was invoked recursively or not, let alone behave differently in the two cases. `return`

**always always always** returns its value to the *direct* caller of this function, whatever it is. It **never never never** "skips" any of those steps and returns the value to a caller further out (such as the outermost caller of a recursive function).

But to help you *see* that this works, lets trace through the evaluation of `fib(3)`

in more detail.

```
fib(3):
3 is not equal to 0 or equal to 1
need to evaluate fib(3 - 1) + fib(3 - 2)
3 - 1 is 2
fib(2):
2 is not equal to 0 or equal to 1
need to evaluate fib(2 - 1) + fib(2 - 2)
2 - 1 is 1
fib(1):
1 is equal to 0 or equal to 1
return 1
fib(1) is 1
2 - 2 is 0
fib(0):
0 is equal to 0 or equal to 1
return 1
fib(0) is 1
so fib(2 - 1) + fib(2 - 2) is 1 + 1
fib(2) is 2
3 - 2 is 1
fib(1):
1 is equal to 0 or equal to 1
return 1
fib(1) is 1
so fib(3 - 1) + fib(3 - 2) is 2 + 1
fib(3) is 3
```

More succinctly, `fib(3)`

returns `fib(2) + fib(1)`

. `fib(1)`

returns 1, but `fib(3)`

returns that *plus* the result of `fib(2)`

. `fib(2)`

returns `fib(1) + fib(0)`

; both of those return `1`

, so adding them together gives `fib(2)`

the result of `2`

. Coming back to `fib(3)`

, which was `fib(2) + fib(1)`

, we're now in a position to say that that is `2 + 1`

which is `3`

.

The key point you were missing was that while `fib(0)`

or `fib(1)`

returns `1`

, those `1`

s form part of the expressions that higher level calls are adding up.

`return n * factorial(n - 1)`

, otherwise the`factorial`

recursion never terminates. – user4815162342 Sep 21 '12 at 6:10