The best way is to use authenticated encryption, and a modern memory-hard entropy-stretching key derivation function such a scrypt to turn the password into a key. The cipher's nounce can be used as salt for the key derivation. With PyCryptodome that could be:
from Crypto.Random import get_random_bytes
from Crypto.Cipher import AES
from Crypto.Protocol.KDF import scrypt
# initialize an AES-128-GCM cipher from password (derived using scrypt) and nonce
def cipherAES(pwd, nonce):
# note: the p parameter should allow use of several processors, but did not for me
# note: changing 16 to 24 or 32 should select AES-192 or AES-256 (not tested)
return AES.new(scrypt(pwd, nonce, 16, N=2**21, r=8, p=1), AES.MODE_GCM, nonce=nonce)
nonce = get_random_bytes(16)
print("deriving key from password and nonce, then encrypting..")
ciphertext, tag = cipherAES(b'pwdHklot2',nonce).encrypt_and_digest(b'bonjour')
# decryption of nonce, ciphertext, tag
print("deriving key from password and nonce, then decrypting..")
plaintext = cipherAES(b'pwdHklot2', nonce).decrypt_and_verify(ciphertext, tag)
print("The message was: " + plaintext.decode())
print("Wrong password or altered nonce, ciphertext, tag")
Note: Code is here to illustrate the principle. In particular, the scrypt parameters should not be fixed, but rather be included in a header before nonce, ciphertext, and tag; and that must be somewhat grouped for sending, and parsed for decryption.
Caveat: nothing in this post should be construed as an endorsement of PyCryptodome's security.
Addition (per request):
We need scrypt or some other form of entropy stretching only because we use a password. We could use a random 128-bit key directly.
PBKDF2-HMAC-SHAn with 100000 iterations (as in the OP's second code fragment there) is only barely passable to resist Hashcat with a few GPUs. It would would be almost negligible compared to other hurdles for an ASIC-assisted attack: a state of the art Bitcoin mining ASIC does more than 2*1010 SHA-256 per Joule, 1 kWh of electricity costing less than $0.15 is 36*105 J. Crunching these numbers, testing the (62(8+1)-1)/(62-1) = 221919451578091 passwords of up to 8 characters restricted to letters and digits cost less than $47 for energy dedicated to the hashing part.
scrypt is much more secure for equal time spent by legitimate users because it requires a lot of memory and accesses thereof, slowing down the attacker, and most importantly making the investment cost for massively parallel attack skyrocket.