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def f(b, n):
    assert isinstance(n, int) and n >= 0
    def _f(n):
        if n == 0: return 1
        else: return b ** _f(n-1)
    return _f(n)

Taking a python class and we have to explain what this does so that a high school algebra student would understand. I am lost. I would appreciate if someone could push me in the right direction without giving me the answer.

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look at the recursion –  user1639464 Sep 3 '12 at 3:01
5  
What part in particular is posing problems? –  Levon Sep 3 '12 at 3:02
1  
Raise an exception for unexpected behaviour, use an assert to sanity check your code for something that should NEVER happen. You would usually remove/disable asserts when deploying your code. –  msanders Sep 3 '12 at 4:17
1  
@bizarrechaos msanders is correct. assert shouldn't be used for validating input, as appears to be the use case here. it's rather a safeguard for checking the programmer's logic, to help catch any bugs that the programmer might have made by erroneous assumptions. for example, if you were implementing a sorting algorithm in a function you might assert that the output IS sorted right before returning it. –  wim Sep 3 '12 at 5:02
1  
BTW, this function has a name: tetration. –  phg Sep 3 '12 at 16:50

3 Answers 3

up vote 3 down vote accepted

The function computes b raised to the power of itself raised to the power of itself n-1 times where n is at least 1. It's equivalent to this simpler non-recursive function:

def g(b, n):
    assert isinstance(n, int) and n >= 0
    ret = 1
    for _ in xrange(n):
        ret = b ** ret
    return ret

It would look something like this written as a mathematical formula:

math formula of function

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Thanks for writing that out in a way that suggests you aren't trying to confuse newcomers by returning functions, instead of values. OP, here's your answer. Please link this to your teacher while you're at it, too. –  Droogans Sep 4 '12 at 2:51
    
@Droogans: Thanks, but I doubt the OP will change their answer at this point. The main reason posted mine was because I thought it was clearer than any of the others I had seen. BTW, the original code is returning a non-function value, it's the value of the result of calling the currently defined local function which is recursive which makes it somewhat difficult to comprehend -- especially since there's really no reason for it and one of the values it uses, b, isn't even passed to it as a normal argument. –  martineau Sep 4 '12 at 3:37

It's seemed the code defined a decorator . The inner definition of the _fn is for easy of the recursion. The code is calculating the following

b^(b^(b^(... (b^(b^0)))...))

i.e., given

b = 2
n = 3

the value will be:

16 = 2^(2^(2^(2^0)
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Many thanks DSM. You're right. It's not a decorator. Updated. –  John Wang Sep 3 '12 at 3:26
    
f(2, 3) returns 16. 2^(2^(2^(2^0) is 16. So your example is wrong but your explanation is helping. –  bizarrechaos Sep 3 '12 at 3:31
    
However f(2, 4) returns 65536 but is 2^(2^(2^(2^(2^0) –  bizarrechaos Sep 3 '12 at 4:11

Taking a python class and we have to explain what this does so that a high school algebra student would understand

function f takes two integers b and n. It raises the first one b to the power of the second one n, and reduces n by 1. This is repeated until n is zero, and the cumulative result is returned.

This doesn't answer any Python related questions like 'what does assert isinstance(n, int) and n >= 0 do', and that I leave as exercise for the OP.

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