The goal of this tutorial is to build a data type that represents a ASCII string in FHE while implementing the to_lower
and to_upper
functions.
An ASCII character is stored in 7 bits. To store an encrypted ASCII we use the FheUint8
.
The uppercase letters are in the range [65, 90]
The lowercase letters are in the range [97, 122]
lower_case = upper_case + UP_LOW_DISTANCE
<=> upper_case = lower_case - UP_LOW_DISTANCE
Where UP_LOW_DISTANCE = 32
Types and methods.
This type will hold the encrypted characters as a Vec<FheUint8>
to implement the functions that change the case.
To use the FheUint8
type, the integer
feature must be activated:
Copy # Cargo.toml
[dependencies]
# Default configuration for x86 Unix machines:
tfhe = { version = "0.4.4" , features = [ "integer" , "x86_64-unix" ]}
Other configurations can be found here .
In the FheAsciiString::encrypt
function, some data validation is done:
The input string can only contain ascii characters.
It is not possible to branch on an encrypted value, however it is possible to evaluate a boolean condition and use it to get the desired result. Checking if the 'char' is an uppercase letter to modify it to a lowercase can be done without using a branch, like this:
Copy pub const UP_LOW_DISTANCE : u8 = 32 ;
fn to_lower (c : u8 ) -> u8 {
if c > 64 && c < 91 {
c + UP_LOW_DISTANCE
} else {
c
}
}
We can remove the branch this way:
Copy pub const UP_LOW_DISTANCE : u8 = 32 ;
fn to_lower (c : u8 ) -> u8 {
c + ((c > 64 ) as u8 & (c < 91 ) as u8 ) * UP_LOW_DISTANCE
}
On an homomorphic integer, this gives
Copy use tfhe :: prelude ::* ;
use tfhe :: FheUint8 ;
pub const UP_LOW_DISTANCE : u8 = 32 ;
fn to_lower (c : & FheUint8 ) -> FheUint8 {
c + (c . gt ( 64 ) & c . lt ( 91 )) * UP_LOW_DISTANCE
}
The whole code is:
Copy use tfhe :: prelude ::* ;
use tfhe :: {generate_keys, set_server_key, ClientKey , ConfigBuilder , FheUint8 };
pub const UP_LOW_DISTANCE : u8 = 32 ;
struct FheAsciiString {
bytes : Vec < FheUint8 >,
}
fn to_upper (c : & FheUint8 ) -> FheUint8 {
c - (c . gt ( 96 ) & c . lt ( 123 )) * UP_LOW_DISTANCE
}
fn to_lower (c : & FheUint8 ) -> FheUint8 {
c + (c . gt ( 64 ) & c . lt ( 91 )) * UP_LOW_DISTANCE
}
impl FheAsciiString {
fn encrypt (string : & str , client_key : & ClientKey ) -> Self {
assert! (
string . chars () . all ( | char | char . is_ascii ()),
"The input string must only contain ascii letters"
);
let fhe_bytes : Vec < FheUint8 > = string
. bytes ()
. map ( | b | FheUint8 :: encrypt (b, client_key))
. collect ();
Self { bytes : fhe_bytes }
}
fn decrypt ( & self, client_key : & ClientKey ) -> String {
let ascii_bytes : Vec < u8 > = self
. bytes
. iter ()
. map ( | fhe_b | fhe_b . decrypt (client_key))
. collect ();
String :: from_utf8 (ascii_bytes) . unwrap ()
}
fn to_upper ( & self) -> Self {
Self {
bytes : self . bytes . iter () . map (to_upper) . collect (),
}
}
fn to_lower ( & self) -> Self {
Self {
bytes : self . bytes . iter () . map (to_lower) . collect (),
}
}
}
fn main () {
let config = ConfigBuilder :: all_disabled ()
. enable_default_integers ()
. build ();
let (client_key, server_key) = generate_keys (config);
set_server_key (server_key);
let my_string = FheAsciiString :: encrypt ( "Hello Zama, how is it going?" , & client_key);
let verif_string = my_string . decrypt ( & client_key);
println! ( "Start string: {verif_string}" );
let my_string_upper = my_string . to_upper ();
let verif_string = my_string_upper . decrypt ( & client_key);
println! ( "Upper string: {verif_string}" );
assert_eq! (verif_string, "HELLO ZAMA, HOW IS IT GOING?" );
let my_string_lower = my_string_upper . to_lower ();
let verif_string = my_string_lower . decrypt ( & client_key);
println! ( "Lower string: {verif_string}" );
assert_eq! (verif_string, "hello zama, how is it going?" );
}
Last updated 9 months ago