Mathematically, your *n*, *e* and *d* appear to respect the RSA rules (i.e. for every prime *r* which divides *n*, *r*^{2} does not divide *n*, and *d* is an inverse of *e* modulo *r-1*). However, RSA is a bit more than that; it also mandates some padding rules, which govern how a message (a sequence of bytes) is to be transformed into an integer modulo *n*, and back. The standard padding (see PKCS#1) implies that at least 11 bytes are added to the message, and the result must still be no longer by *n*. Hence, with a 128-bit modulus
like the one you show, the maximum input message length for encryption will be 5 bytes.

Also, some RSA implementations will refuse to work with RSA keys which are much too small for security. A 128-bit modulus can be factor in a matter of seconds (see this page for a factorization Java applet, which uses ECM and quadratic sieve to factor relatively small numbers such as yours). The current record in factorization is 768 bits; a modulus length of at least 1024 bits is recommended for short-term security. A typical RSA implementation will accept to use 512-bit keys, but many will reject anything shorter than that.

Another possible issue is in the relative order of *p* and *q*. The equations laid out in PKCS#1 assume that *p > q* (otherwise, there is an extra subtraction to perform in the CRT part). If you have *p < q*, then some implementations may get it wrong (I encountered that with Microsoft's RSA standard implementation in Windows). Just compare *p* with *q* and swap them if necessary.

Still on the practicality level, some widespread RSA implementations will refuse a RSA key such that the public exponent *e* does not fit within a 32-bit integer (this includes the RSA implementation used in Windows, in particular by Internet Explorer to connect to HTTPS Web sites -- so when I write "widespread" I mean it). RSA security does not seem to be impacted by the choice of *e*, so it is customary to choose a small *e*, which speeds up the part which uses the public key (i.e. encryption, as opposed to decryption, or signature verification, as opposed to signature generation). *e = 3* is about the best you could do, but for traditional reasons (including an historical misunderstanding on an alleged weakness), *e=65537* is often used. You just need to have *e* relatively prime to *p-1* and *q-1*. In a practical implementation, you choose *e* first, then loop within the generation for *p* and *q* as long as they do not match that additional rule.

From a security point of view:

Your generation process is not uniform, in that some prime integers will be selected more often than others. In particular, a prime *p* such that *p+2* is also prime will almost never be selected. With a proper modulus size, this *should* not be an issue (that special kind of bias was studied and found out not to be a big issue) but it is bad public relations nonetheless.

Your *n* may be a bit smaller than your target size, in case both *p* and *q* are close to the lower bound of their generation range. A simple way to avoid that is to restrict the range to *[sqrt(2)*2*^{b-1}, 2^{b}] for both *p* and *q*.

I cannot vouch for the security of the `random`

module you use. A *cryptographically secure* random number generator is not an easy thing to do.

Generally speaking, properly implementing RSA without leaking confidential information through various side channels (timing, cache memory usage...) is not an easy task. If you want security in a practical setup, you should really *really* use an existing package. I believe that Python has ways to interface with OpenSSL.

`M2Crypto.RSA.gen_key`

? – J.F. Sebastian May 9 '10 at 23:35