I wrote code to generate pseudo-random prime numbers, public/private keys, etc. for the sake of implementing RSA encryption (for personal amusement and nothing more). I am able to successfully encode text, generate the public/private key, encrypt, decrypt, and decode when the encoded text is an integer ~10^12 or less. e.g.

```
original message: hello
plaintext equivalent: 448378203247
public key: (540594823829, 65537)
private key: (540594823829, 261111754433)
ciphertext: 63430225682
```

Decrypting the ciphertext successfully returns the original plaintext.

However, when my encoded text is a larger integer, the process fails. e.g.

```
original message: a man a plan a canal panama
plaintext equivalent: 39955594125525792198857762901926727877852838348601974063966023009
public key: (662173326571, 65537)
private key: (662173326571, 29422219265)
ciphertext: 429717871098
```

In this case the ciphertext is much much smaller than the plaintext, which makes one suspect that something in the encryption process went wrong. And sure enough, I decrypt the ciphertext and get 58514793315 (clearly not the original plaintext).

I'm thinking the issue is how Python implements large numbers/calculations with large numbers, and the fact that I'm not aware of how to deal with that. For what it's worth my code to encrypt/decrypt is simply

```
pow(m, e, n) # plaintext, encryption exponent, modulus
pow(c, d, n) # ciphertext, decryption exponent, modulus
```

and the code for encoding text is from http://gist.github.com/barrysteyn/4184435#file_convert_text_to_decimal.py

How do I ensure that calculations with these large integers are carried out as I wish (and do not result in truncated/incorrect answers)?