Tutorial

Writing an homomorphic circuit using shortint

Key Generation

tfhe::shortint provides 2 key types:

ClientKey
ServerKey

The ClientKey is the key that encrypts and decrypts messages (integer values up to 8 bits here), thus this key is meant to be kept private and should never be shared. This key is created from parameter values that will dictate both the security and efficiency of computations. The parameters also set the maximum number of bits of message encrypted in a ciphertext.

The ServerKey is the key that is used to actually do the FHE computations. It contains (among other things) a bootstrapping key and a keyswitching key. This key is created from a ClientKey that needs to be shared to the server, therefore it is not meant to be kept private. A user with a ServerKey can compute on the encrypted data sent by the owner of the associated ClientKey.

To reflect that, computation/operation methods are tied to the ServerKey type.

use tfhe::shortint::prelude::*;

fn main()  {
    // We generate a set of client/server keys, using the default parameters:
    let (client_key, server_key) = gen_keys(Parameters::default());
}

Encrypting values

Once the keys have been generated, the client key is used to encrypt data:

use tfhe::shortint::prelude::*;

fn main() {
    // We generate a set of client/server keys, using the default parameters:
   let (client_key, server_key) = gen_keys(Parameters::default());

    let msg1 = 1;
    let msg2 = 0;

    // We use the client key to encrypt two messages:
    let ct_1 = client_key.encrypt(msg1);
    let ct_2 = client_key.encrypt(msg2);
}

Encrypting values using a public key

Once the keys have been generated, the client key is used to encrypt data:

use tfhe::shortint::prelude::*;

fn main() {
    // We generate a set of client/server keys, using the default parameters:
   let (client_key, _) = gen_keys(Parameters::default());
   let public_key = PublicKey::new(&client_key);

    let msg1 = 1;
    let msg2 = 0;

    // We use the client key to encrypt two messages:
    let ct_1 = public_key.encrypt(msg1);
    let ct_2 = public_key.encrypt(msg2);
}

Computing and decrypting

With our server_key and encrypted values, we can now do an addition and then decrypt the result.

use tfhe::shortint::prelude::*;

fn main() {
    // We generate a set of client/server keys, using the default parameters:
    let (client_key, server_key) = gen_keys(Parameters::default());

    let msg1 = 1;
    let msg2 = 0;

    let modulus = client_key.parameters.message_modulus.0;

    // We use the client key to encrypt two messages:
    let ct_1 = client_key.encrypt(msg1);
    let ct_2 = client_key.encrypt(msg2);

    // We use the server public key to execute an integer circuit:
    let ct_3 = server_key.unchecked_add(&ct_1, &ct_2);

    // We use the client key to decrypt the output of the circuit:
    let output = client_key.decrypt(&ct_3);
    assert_eq!(output, (msg1 + msg2) % modulus as u64);
}

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Last updated 3 years ago

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hashtagWriting an homomorphic circuit using shortint

hashtagKey Generation

hashtagEncrypting values

hashtagEncrypting values using a public key

hashtagComputing and decrypting

Writing an homomorphic circuit using shortint

Key Generation

Encrypting values

Encrypting values using a public key

Computing and decrypting