# Modular exponentiation implementation in Python 3

Basically this is a homework question. I'm supposed to implement these two pseudo-code algorithms in Python3. I'm doing something wrong and I can't figure out what (it seems like this should be simple so I'm not sure what/where I botched this. It could be my algorithm or my lack of experience with Python. I'm not sure which.).

Please tell me what I did wrong, don't post any code. If I get code for an answer I'll get pegged for plagiarism (which I very much do not want).

The first algorithm (base expansion):

``````
procedure base expansion(n, b: positive integers with b > 1)
q := n
k := 0
while q ≠ 0
ak := q mod b
q := q div b
k := k + 1
return (ak-1, ... , a1, a0) {(ak-1 ... a1 a0)b is the base b expansion of n}
``````

the second algorithm (modular expansion):

``````
procedure modular exponentiation(b: integer, n = (ak-1ak-2...a1a0)2, m: positive integers)
x := 1
power := b mod m
for i := 0 to k - 1
if ai = 1 then x := (x * power) mod m
power := (power * power) mod m
return x {x equals bn mod m}
``````

Seems simple enough anyway, here's what I implemented in Python3 (and I beg forgiveness of all Python programmers out there, this is a very new language for me)

``````def baseExp(n, b):
q = n
a = []
while (q != 0):
a.append(q % b)
q = q // b
pass
return a

def modularExp(b, n, m):
a = baseExp(n, b)
x = 1
power = b % m
for i in range(0, len(a)):
if (a[i] == 1):
x = (x * power) % m
pass
power = (power * power) % m
pass
return x
``````

This seems like it should work, but when I attempt to solve 7644 mod 645 I get the answer 79 but the right answer should be 436.

If anyone could point out my mistakes without actually giving me any code I'd be extremely appreciative.

-
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## 1 Answer

Your method will only work if b equals 2, which is same as exponentiation by squaring but it will fail in cases with b > 2. Here's how:

Your string n can contain numbers in the range [0,b-1] as it is the representation of number n in base b. In your code, you only check for digit 1, and in the case of b = 7, there can be any digit in the range [0,6]. You have to modify your algorithm as follows :

``````// take appropriate remainders where required
// Correction 1 :
In the for loop,
Check if a[i] = 1, then x = x * power
else if a[i] = 2, then x = x * power^2
else if a[i] = 3, then x = x * power^3
.
.
.
.
till a[i] = b-1, then x = x * power^(b-1)
// Correction 2 :
After checking a[i]
power = power^b and not power = power^2 which is only good for b = 2
``````

You should now get the correct answer.

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Thanks a bunch. I've been wracking my brain all week and I've been super sick. The changes you suggested make the algorithm work. What I don't get is why the pseudo-code in my book wasn't written out like the way you described (I double checked my book to make sure I didn't just mistype it here, so either I don't understand the book's notation or it was wrong). Thanks again, you were a lifesaver! –  Son of Lysander Sep 14 '13 at 19:02
It seems like the pseudo code for 'procedure modular exponentiation' in your book was written specifically for b = 2 as it is indicated in 'n = (ak-1ak-2...a1a0)2' while it carries the subscript 'b' instead of 2 in 'procedure base expansion'. –  sanchit.h Sep 14 '13 at 19:06
OH MY GOSH! It took me a couple hours, but I actually figured out what's supposed to happen (ironically it was your last comment that made me figure it out). For the line `a = baseExp(n, b)` if we change it to `a = baseExp(n, 2)` it expands it into binary which is BASE 2 and works for the original pseudo-code! That's why the book wrote it that way!I have to DOUBLE thank you, I wouldn't have figured that out if it weren't for your observation! –  Son of Lysander Sep 15 '13 at 0:23
Glad I could help :) –  sanchit.h Sep 15 '13 at 8:04
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