48

I need a function that takes n and returns 2n - 1 . It sounds simple enough, but the function has to be recursive. So far I have just 2n:

def required_steps(n):
    if n == 0:
        return 1
    return 2 * req_steps(n-1)

The exercise states: "You can assume that the parameter n is always a positive integer and greater than 0"

  • 4
    Just for the record, it should be vastly more efficient to do it like a normal person with a shift and subtract. Python integers are arbitrary width so 1 << n can't overflow. This seems to be an exercise in inventing a way to decompose (1<<n) - 1 into multiple steps, perhaps setting each bit one at a time like some answers show. – Peter Cordes Oct 14 at 23:57
  • 8
    def fn(n): if n == 0: return 1; return (2 << n) - fn(0); # technically recursive – MooseBoys Oct 15 at 6:28
  • 3
    @Voo: Not Carl, but please list me everything that is contained in C:\MyFolder – Flater Oct 16 at 11:11
  • 1
    @Voo: Dependency or not is irrelevant for an exercise which purely focuses on teaching the concept of recursion. I could make a basic mocked set of classes/methods that students could use. You're focusing on something that is completely besides the point of the exercise. Using file system navigation is a good example because students generally understand the inherently recurrent nature of folders and files (i.e. folders can be nested in each other nigh indefinitely) – Flater Oct 16 at 11:47
  • 1
    @Voo No I'm saying that you can teach recursion by showing a recursive data structure. I have no idea why you struggle grasping this. – Flater Oct 16 at 21:46
53

2**n -1 is also 1+2+4+...+2n-1 which can made into a single recursive function (without the second one to subtract 1 from the power of 2).

Hint: 1+2*(1+2*(...))

Solution below, don't look if you want to try the hint first.


This works if n is guaranteed to be greater than zero (as was actually promised in the problem statement):

def required_steps(n):
    if n == 1: # changed because we need one less going down
        return 1
    return 1 + 2 * required_steps(n-1)

A more robust version would handle zero and negative values too:

def required_steps(n):
    if n < 0:
        raise ValueError("n must be non-negative")
    if n == 0:
        return 0
    return 1 + 2 * required_steps(n-1)

(Adding a check for non-integers is left as an exercise.)

  • 4
    but required_steps(0) now causes infinite recursion – Thank you Oct 14 at 14:17
  • 7
    2^0 - 1 == 0. Add another if for that case. – h4z3 Oct 14 at 14:18
  • 9
    @user633183 Yes, I know what a total function is. Do you? Because it won't ever be a total function. Nor are the other answers total functions. And yes, more code would be needed to make them total functions. - As I said, we have no domain. What should we assume our domain is? Even if it's just int, we don't know what to do when n<0. Calculate? Throw an error? Return 0? In this case, we only can do a partial function (define it for things we know what the result is). – h4z3 Oct 14 at 14:39
  • 4
    The base case in the OP’s code is 0 and uses n - 1 for the subproblem. A domain of Natural Numbers seems like a good fit. – Thank you Oct 14 at 14:47
  • 4
    Thank you so much! In my humble opinion, this is the best solution for my specific problem. I didn't state possible values for n, really sorry! I know that is kinda important... the exercise states: "You can assume that the parameter n is always a positive integer and greater than 0" – Kajice Oct 14 at 15:40
36

To solve a problem with a recursive approach you would have to find out how you can define the function with a given input in terms of the same function with a different input. In this case, since f(n) = 2 * f(n - 1) + 1, you can do:

def required_steps(n):
    return n and 2 * required_steps(n - 1) + 1

so that:

for i in range(5):
    print(required_steps(i))

outputs:

0
1
3
7
15
9

You can extract the really recursive part to another function

def f(n):
    return required_steps(n) - 1

Or you can set a flag and define just when to subtract

def required_steps(n, sub=True):
    if n == 0: return 1
    return 2 * required_steps(n-1, False) - sub

>>> print(required_steps(10))
1023
0

Using an additional parameter for the result, r -

def required_steps (n = 0, r = 1):
  if n == 0:
    return r - 1
  else:
    return required_steps(n - 1, r * 2)

for x in range(6):
  print(f"f({x}) = {required_steps(x)}")

# f(0) = 0
# f(1) = 1
# f(2) = 3
# f(3) = 7
# f(4) = 15
# f(5) = 31

You can also write it using bitwise left shift, << -

def required_steps (n = 0, r = 1):
  if n == 0:
    return r - 1
  else:
    return required_steps(n - 1, r << 1)

The output is the same

  • 2
    Unnecessary to involve bitwise operations for a simple multiplication exercise.. not readable at all. Also, no need for the else clause in either function – rafaelc Oct 14 at 14:56
  • 9
    Yep. r*2 is very readable, r << 1 is not readable at all – rafaelc Oct 14 at 15:55
  • 2
    Inventing a 2nd parameter just turns this into a loop that shifts left n times and then subtracts 1. Seems even less elegant then necessary, although the whole thing is an exercise in inefficiency vs. (1<<n) - 1. – Peter Cordes Oct 15 at 1:03
  • 1
    @PeterCordes: Moving the state into an accumulator parameter is the standard way of transforming a recursive call into a tail-recursive call. Now, unfortunately, Python doesn't support Proper Tail Calls, not even Proper Tail Recursion, but that doesn't mean that this isn't a useful technique to learn so that you can apply it in other languages that do implement Proper Tail Calls or at least Proper Tail Recursion. – Jörg W Mittag Oct 15 at 3:10
  • 1
    @JörgWMittag Yes, but in this case it's hard to disguise the fact that it would be more natural as a loop. Maybe it's just that I spend so much time on assembly language and performance, but writing a "loop" by using tail-recursion seems pointless in an imperative language when you could just write a loop. Or perhaps what bothers me about this answer is just the choice of how to decompose: into one-at-a-time shifts and then a final subtract as the basecase. Probably a combination of both. – Peter Cordes Oct 15 at 3:21
0

Have a placeholder to remember original value of n and then for the very first step i.e. n == N, return 2^n-1

n = 10
# constant to hold initial value of n
N = n
def required_steps(n, N):
    if n == 0:
        return 1
    elif n == N:
        return 2 * required_steps(n-1, N) - 1
    return 2 * required_steps(n-1, N)

required_steps(n, N)
-1

One way to get the offset of "-1" is to apply it in the return from the first function call using an argument with a default value, then explicitly set the offset argument to zero during the recursive calls.

def required_steps(n, offset = -1):
    if n == 0:
        return 1
    return offset + 2 * required_steps(n-1,0)
-1

On top of all the awesome answers given earlier, below will show its implementation with inner functions.

def outer(n):
    k=n
    def p(n):
        if n==1:
            return 2
        if n==k:
            return 2*p(n-1)-1
        return 2*p(n-1)
    return p(n)

n=5
print(outer(n))

Basically, it is assigning a global value of n to k and recursing through it with appropriate comparisons.

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