Let's take the general case:
you built a function F1() that returns True with probability P (in your case, P=60%).
now you build the second function this way:

```
F2():
result1 = F1()
result2 = F1()
if result1 = True and result2 = False: return True
elif result1 = False and result2 = True: return False
else: F2()
```

In this case, the probability of running F1 twice and obtaining (True,False) is the same as obtaining (False,True) and it's P * (1-P). Instead, if you get either (True,True) or (False,False) you call F2 recursively. This means, that after running F2 you always obtain True or False with probability 1/2 since the first two branches have equal probabilities, and the third will always give you the result of a function with 1/2 probability.

I am making this a community wiki in case someone wants to make my answer more clear. I realize it might be a little hard to explain the concept.

*The average number of calls*

The probability that the function F2() terminates right after n recursive calls is:

{(1-P)^2+P^2}^n*2P(1-P)

Therefore, the average number of recursive calls required is:

\Sum_{i=0}^\infty i*{(1-P)^2+P^2}^i*2P(1-P)

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