Inspired by the "encoding scheme" of the answer to this question, I implemented my own encoding algorithm in Python.
Here is what it looks like:
import random from math import pow from string import ascii_letters, digits # RFC 2396 unreserved URI characters unreserved = '-_.!~*\'()' characters = ascii_letters + digits + unreserved size = len(characters) seq = range(0,size) # Seed random generator with same randomly generated number random.seed(914576904) random.shuffle(seq) dictionary = dict(zip(seq, characters)) reverse_dictionary = dict((v,k) for k,v in dictionary.iteritems()) def encode(n): d =  n = n while n > 0: qr = divmod(n, size) n = qr d.append(qr) chars = '' for i in d: chars += dictionary[i] return chars def decode(str): d =  for c in str: d.append(reverse_dictionary[c]) value = 0 for i in range(0, len(d)): value += d[i] * pow(size, i) return value
The issue I'm running into is encoding and decoding very large integers. For example, this is how a large number is currently encoded and decoded:
s = encode(88291326719355847026813766449910520462) # print s -> "3_r(AUqqMvPRkf~JXaWj8" i = decode(s) # print i -> "8.82913267194e+37" # print long(i) -> "88291326719355843047833376688611262464"
The highest 16 places match up perfectly, but after those the number deviates from its original.
I assume this is a problem with the precision of extremely large integers when dividing in Python. Is there any way to circumvent this problem? Or is there another issue that I'm not aware of?