I'm developing an Py4a (Python in SL4a) application running on an Android phone. The application collects some sensitive data, and then sends it via e-mail, using the smtplib module. To assure necessary protection, I need to encrypt that information. As phone is considered to be unsafe device, I have to use the public-key encryption, and only recipient's public key should be stored in the phone.
The standard Py4a distribution contains two packages supporting public key cryptography:
the ssl
and gdata
.
Unfortunately none of them provides a ready to use function, allowing me to encrypt longer information with the private key.
Well, I know that in fact I should generate a random temporary symmetric key, encrypt my information with that key, and finally encrypt only this key with the recipient's public key. However there are some details which must be considered to obtain secure solution...
So here my question comes. Is there any simple encryption library, well suited to Py4a (ie. based on the cryptographic libraries already available in Py4a - like ssl and gdata.Crypto) providing easy to use public key encryption?
Update 2013.06.13
I have performed some experiments with the gdata library in Py4a. Finally I have get the following "quick&dirty" solution:
import gdata.tlslite.utils.keyfactory as rk
#Generate the recipient's RSA key
sec=rk.generateRSAKey(1024)
#obtain the publickey, which will be stored
#in the sender mobile phone
pubxml=sec.writeXMLPublicKey()
print pubxml
#Create the public key from XML
pub=rk.parseXMLKey(pubxml)
#
#Now lets simulate the sender
#It has only access to "pub"
#
import gdata.tlslite.utils.PyCrypto_AES as sk
import gdata.tlslite.utils.cipherfactory as cf
#Generate random key and initioalization vectors
key=sk.getRandomBytes(32)
iv=sk.getRandomBytes(16)
#Here we should check if the key and iv are reasonable
#Now we accept them as they are
#Text to encrypt
txt1="Strictly secret unknown text!"
#Pad the text to the length N*16
padlen=16-(len(txt1) % 16)
if padlen:
txt1=txt1.ljust(len(txt1)+padlen, " ")
#Create the AES key
ak=cf.createAES(key.tostring(),iv.tostring())
#Encrypt text
ctxt1=ak.encrypt(txt1)
#Encrypt key and initialization vector with recipients publickey
ckey1=pub.encrypt(key+iv)
#
# Now we simulate the recipient
# It has its secret key 'sec', and received encrypted key
# and iv from the sender in ckey1. It also receives ctxt1
#
pkey1=sec.decrypt(ckey1)
pkey=pkey1[0:32]
piv=pkey1[32:48]
# Now we decipher the text
pak=cf.createAES(pkey.tostring(),piv.tostring())
ptxt1=pak.decrypt(ctxt1)
# Print the deciphered text
print ptxt1
Probably this solution is far from being optimal, but it at least works.