siwei
/
dify


			
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							from Crypto.Cipher import AES
from Crypto.Hash import SHA256
from Crypto.PublicKey import ECC
from Crypto.Util.Padding import pad, unpad


class ECC_AES:
    def __init__(self, curve='P-256'):
        self.curve = curve
        self._aes_key = None
        self._private_key = None

    def _derive_aes_key(self, ecc_key, nonce):
        if not self._aes_key:
            hasher = SHA256.new()
            hasher.update(ecc_key.export_key(format='DER') + nonce.encode())
            self._aes_key = hasher.digest()[:32]
        return self._aes_key

    def generate_key_pair(self):
        private_key = ECC.generate(curve=self.curve)
        public_key = private_key.public_key()

        pem_private = private_key.export_key(format='PEM')
        pem_public = public_key.export_key(format='PEM')

        return pem_private, pem_public

    def load_private_key(self, private_key_pem):
        self._private_key = ECC.import_key(private_key_pem)
        self._aes_key = None

    def encrypt(self, text, nonce):
        if not self._private_key:
            raise ValueError("Private key not loaded")

        # Generate AES key using ECC private key and nonce
        aes_key = self._derive_aes_key(self._private_key, nonce)

        # Encrypt data using AES key
        cipher = AES.new(aes_key, AES.MODE_ECB)
        padded_text = pad(text.encode(), AES.block_size)
        ciphertext = cipher.encrypt(padded_text)

        return ciphertext

    def decrypt(self, ciphertext, nonce):
        if not self._private_key:
            raise ValueError("Private key not loaded")

        # Generate AES key using ECC private key and nonce
        aes_key = self._derive_aes_key(self._private_key, nonce)

        # Decrypt data using AES key
        cipher = AES.new(aes_key, AES.MODE_ECB)
        padded_plaintext = cipher.decrypt(ciphertext)
        plaintext = unpad(padded_plaintext, AES.block_size)

        return plaintext.decode()


if __name__ == '__main__':
    ecc_aes = ECC_AES()

    # Generate key pairs for the user
    private_key, public_key = ecc_aes.generate_key_pair()
    ecc_aes.load_private_key(private_key)
    nonce = "THIS-IS-USER-ID"

    print(private_key)

    # Encrypt a message
    message = "Hello, this is a secret message!"
    encrypted_message = ecc_aes.encrypt(message, nonce)
    print(f"Encrypted message: {encrypted_message.hex()}")

    # Decrypt the message
    decrypted_message = ecc_aes.decrypt(encrypted_message, nonce)
    print(f"Decrypted message: {decrypted_message}")

    # Check if the original message and decrypted message are the same
    assert message == decrypted_message, "Original message and decrypted message do not match"