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Sebastian Gesemann
2015-01-29 17:03:31 +01:00
commit 3ab77d5b31
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.gitignore vendored Normal file
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/target

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[root]
name = "secretshare"
version = "0.0.1"
dependencies = [
"getopts 0.2.0 (registry+https://github.com/rust-lang/crates.io-index)",
"rustc-serialize 0.2.10 (registry+https://github.com/rust-lang/crates.io-index)",
]
[[package]]
name = "getopts"
version = "0.2.0"
source = "registry+https://github.com/rust-lang/crates.io-index"
[[package]]
name = "rustc-serialize"
version = "0.2.10"
source = "registry+https://github.com/rust-lang/crates.io-index"

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Cargo.toml Normal file
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[package]
name = "secretshare"
version = "0.0.1"
authors = ["Sebastian Gesemann <s.gesemann@gmail.com>"]
[dependencies]
getopts = "0.2.0"
rustc-serialize = "0.2.10"

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//! This module provides the Gf256 type which is used to represent
//! elements of a finite field wich 256 elements.
use std::ops::{ Add, Sub, Mul, Div };
use std::sync::{ Once, ONCE_INIT };
const POLY: u8 = 0x1D; // represents x^8 + x^4 + x^3 + x^2 + 1
/// replicates the least significant bit to every other bit
#[inline]
#[allow(unsigned_negation)]
fn mask(bit: u8) -> u8 {
-(bit & 1)
}
/// multiplies a polynomial with x and returns the residual
/// of the polynomial division with POLY as divisor
#[inline]
fn xtimes(poly: u8) -> u8 {
(poly << 1) ^ (mask(poly >> 7) & POLY)
}
/// Tables used for multiplication and division
struct Tables {
exp: [u8; 256],
log: [u8; 256],
inv: [u8; 256]
}
static INIT: Once = ONCE_INIT;
static mut TABLES: Tables = Tables {
exp: [0; 256],
log: [0; 256],
inv: [0; 256]
};
fn get_tables() -> &'static Tables {
INIT.call_once(|| {
// mutable access is fine because of synchronization via INIT
let tabs = unsafe { &mut TABLES };
let mut tmp = 1;
for power in 0..255us {
tabs.exp[power] = tmp;
tabs.log[tmp as usize] = power as u8;
tmp = xtimes(tmp);
}
tabs.exp[255] = 1;
for x in 1..256us {
let l = tabs.log[x];
let nl = if l==0 { 0 } else { 255 - l };
let i = tabs.exp[nl as usize];
tabs.inv[x] = i;
}
});
// We're guaranteed to have TABLES initialized by now
return unsafe { &TABLES };
}
/// Type for elements of a finite field with 256 elements
#[derive(Copy,Clone,PartialEq,Eq)]
pub struct Gf256 {
pub poly: u8
}
impl Gf256 {
/// returns the additive neutral element of the field
#[inline]
pub fn zero() -> Gf256 {
Gf256 { poly: 0 }
}
/// returns the multiplicative neutral element of the field
#[inline]
pub fn one() -> Gf256 {
Gf256 { poly: 1 }
}
#[inline]
pub fn from_byte(b: u8) -> Gf256 {
Gf256 { poly: b }
}
#[inline]
pub fn to_byte(&self) -> u8 {
self.poly
}
pub fn log(&self) -> Option<u8> {
if self.poly == 0 {
None
} else {
let tabs = get_tables();
Some(tabs.log[self.poly as usize])
}
}
pub fn exp(power: u8) -> Gf256 {
let tabs = get_tables();
Gf256 { poly: tabs.exp[power as usize] }
}
/*
pub fn inv(&self) -> Option<Gf256> {
self.log().map(|l| Gf256::exp(255 - l))
}
*/
}
impl Add<Gf256> for Gf256 {
type Output = Gf256;
#[inline]
fn add(self, rhs: Gf256) -> Gf256 {
Gf256::from_byte(self.poly ^ rhs.poly)
}
}
impl Sub<Gf256> for Gf256 {
type Output = Gf256;
#[inline]
fn sub(self, rhs: Gf256) -> Gf256 {
Gf256::from_byte(self.poly ^ rhs.poly)
}
}
impl Mul<Gf256> for Gf256 {
type Output = Gf256;
fn mul(self, rhs: Gf256) -> Gf256 {
if let (Some(l1), Some(l2)) = (self.log(), rhs.log()) {
let tmp = ((l1 as u16) + (l2 as u16)) % 255;
Gf256::exp(tmp as u8)
} else {
Gf256 { poly: 0 }
}
}
}
impl Div<Gf256> for Gf256 {
type Output = Gf256;
fn div(self, rhs: Gf256) -> Gf256 {
let l2 = rhs.log().expect("division by zero");
if let Some(l1) = self.log() {
let tmp = ((l1 as u16) + 255 - (l2 as u16)) % 255;
Gf256::exp(tmp as u8)
} else {
Gf256 { poly: 0 }
}
}
}

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#![feature(collections)]
#![feature(io)]
#![feature(os)]
#![feature(rand)]
extern crate "rustc-serialize" as serialize;
extern crate getopts;
use std::os;
use std::rand::{ Rng, OsRng };
use std::iter::repeat;
use std::old_io::{ stdio, IoError, IoErrorKind, IoResult, BufferedReader };
use serialize::base64::{ self, FromBase64, ToBase64 };
use getopts::Options;
use gf256::Gf256;
mod gf256;
fn new_vec<T: Clone>(n: usize, x: T) -> Vec<T> {
repeat(x).take(n).collect()
}
fn other_io_err(s: &'static str) -> IoError {
IoError {
kind: IoErrorKind::OtherIoError,
desc: s,
detail: None
}
}
/// evaluates a polynomial at x=1, 2, 3, ... n (inclusive)
fn encode<W: Writer>(src: &[u8], n: u8, w: &mut W) -> IoResult<()> {
for raw_x in 1 .. ((n as u16) + 1) {
let x = Gf256::from_byte(raw_x as u8);
let mut fac = Gf256::one();
let mut acc = Gf256::zero();
for &coeff in src.iter() {
acc = acc + fac * Gf256::from_byte(coeff);
fac = fac * x;
}
try!(w.write_u8(acc.to_byte()));
}
Ok(())
}
/// evaluates an interpolated polynomial at `raw_x` where
/// the polynomial is determined using Lagrangian interpolation
/// based on the given x/y coordinates `src`.
fn lagrange_interpolate(src: &[(u8, u8)], raw_x: u8) -> u8 {
let x = Gf256::from_byte(raw_x);
let mut sum = Gf256::zero();
for (i, &(raw_xi, raw_yi)) in src.iter().enumerate() {
let xi = Gf256::from_byte(raw_xi);
let yi = Gf256::from_byte(raw_yi);
let mut lix = Gf256::one();
for (j, &(raw_xj, _)) in src.iter().enumerate() {
if i != j {
let xj = Gf256::from_byte(raw_xj);
lix = lix * (x - xj) / (xi - xj);
}
}
sum = sum + lix * yi;
}
sum.to_byte()
}
fn secret_share(src: &[u8], k: u8, n: u8) -> IoResult<Vec<Vec<u8>>> {
let mut result = Vec::with_capacity(n as usize);
for _ in 0 .. (n as usize) {
result.push(new_vec(src.len(), 0u8));
}
let mut col_in = new_vec(k as usize, 0u8);
let mut col_out = Vec::with_capacity(n as usize);
let mut osrng = try!(OsRng::new());
for (c, &s) in src.iter().enumerate() {
col_in[0] = s;
osrng.fill_bytes(&mut col_in[1..]);
col_out.clear();
try!(encode(&*col_in, n, &mut col_out));
for (&y, share) in col_out.iter().zip(result.iter_mut()) {
share[c] = y;
}
}
Ok(result)
}
enum Action {
Encode(u8, u8), // k and n parameter
Decode
}
fn parse_k_n(s: &str) -> Option<(u8, u8)> {
let mut iter = s.split(',');
let first = match iter.next() { Some(x) => x, None => return None };
let second = match iter.next() { Some(x) => x, None => return None };
let k = match first.parse() { Some(x) => x, None => return None };
let n = match second.parse() { Some(x) => x, None => return None };
Some((k, n))
}
/// tries to read everything but stops early if the input seems to be
/// larger than `max` bytes and returns an IoError in this case
fn read_no_more_than<R: Reader>(r: &mut R, max: usize) -> IoResult<Vec<u8>> {
let mut data = Vec::new();
loop {
if let Err(e) = r.push(max + 1 - data.len(), &mut data) {
if e.kind == IoErrorKind::EndOfFile {
break; // EOF condition is actually OK
} else {
return Err(e);
}
}
if data.len() > max {
return Err(other_io_err("Input too long"));
}
}
Ok(data)
}
fn perform_encode(k: u8, n: u8) -> IoResult<()> {
let secret = try!(read_no_more_than(&mut stdio::stdin(), 0x10000));
let shares = try!(secret_share(&*secret, k, n));
for (index, share) in shares.iter().enumerate() {
println!("{}-{}-{}", k, index+1, share.to_base64(base64::STANDARD));
}
Ok(())
}
/// reads shares from stdin and returns Ok(k, shares) on success
/// where shares is a Vec<(u8, Vec<u8>)> representing x-coordinates
/// and share data.
fn read_shares() -> IoResult<(u8, Vec<(u8,Vec<u8>)>)> {
let mut stdin = BufferedReader::new(stdio::stdin());
let mut opt_k_l: Option<(u8, usize)> = None;
let mut counter = 0u8;
let mut shares = Vec::new();
for line in stdin.lines() {
let line = try!(line);
let parts: Vec<_> = line.split('-').collect();
let (k, n, raw) = match
Some(parts).and_then(|p| {
if p.len() != 3 { None } else { Some(p) }
}).and_then(|p| {
let mut iter = p.into_iter();
let p1 = iter.next().unwrap().parse::<u8>();
let p2 = iter.next().unwrap().parse::<u8>();
let p3 = iter.next().unwrap();
match (p1, p2) {
(Some(k), Some(n)) => Some((k,n,p3)),
_ => None
}
}).and_then(|(k,n,text)| {
match text.from_base64() {
Ok(v) => Some((k,n,v)),
_ => None
}
}) {
None => return Err(other_io_err("Share parse error")),
Some(s) => s
};
if let Some((ck,cl)) = opt_k_l {
if ck != k || cl != raw.len() {
return Err(other_io_err("Incompatible shares"));
}
} else {
opt_k_l = Some((k,raw.len()));
}
shares.push((n, raw));
counter += 1;
if counter == k {
return Ok((k, shares));
}
}
Err(other_io_err("No shares"))
}
fn perform_decode() -> IoResult<()> {
let (k, shares) = try!(read_shares());
assert!(!shares.is_empty());
let slen = shares[0].1.len();
let mut col_in = Vec::with_capacity(k as usize);
let mut secret = Vec::with_capacity(slen);
for byteindex in 0 .. slen {
col_in.clear();
for s in shares.iter().take(k as usize) {
col_in.push((s.0, s.1[byteindex]));
}
secret.push(lagrange_interpolate(&*col_in, 0u8));
}
let mut out = stdio::stdout_raw();
try!(out.write_all(&*secret));
out.flush()
}
fn main() {
let mut stderr = stdio::stderr();
let args = os::args();
let mut opts = Options::new();
opts.optflag("h", "help", "print this help text");
opts.optflag("d", "decode", "for decoding");
opts.optopt("e", "encode", "for encoding, K is the required number of shares, \
N is the number of shares to generate. 1 <= K <= N <= 255", "K,N");
let opt_matches = match opts.parse(args.tail()) {
Ok(m) => m,
Err(f) => panic!(f.to_string())
};
if args.len() < 2 || opt_matches.opt_present("h") {
println!(
"The program secretshare is an implementation of Shamir's secret sharing scheme.\n\
It is applied byte-wise within a finite field for arbitraty long secrets.\n");
println!("{}", opts.usage("Usage: secretshare [options]"));
return;
}
let action: Result<_,_> =
match (opt_matches.opt_present("e"), opt_matches.opt_present("d")) {
(false, false) => Err("Nothing to do! Use -e or -d"),
(true, true) => Err("Use either -e or -d and not both"),
(false, true) => Ok(Action::Decode),
(true, false) => {
if let Some(param) = opt_matches.opt_str("e") {
if let Some((k,n)) = parse_k_n(&*param) {
Ok(Action::Encode(k,n))
} else {
Err("Could not parse K,N parameters")
}
} else {
Err("No parameter for -e or -d provided")
}
}
};
let result =
match action {
Ok(Action::Encode(k,n)) => perform_encode(k,n),
Ok(Action::Decode) => perform_decode(),
Err(e) => {
drop(writeln!(&mut stderr, "Error: {}", e));
os::set_exit_status(1);
return;
}
};
if let Err(e) = result {
drop(writeln!(&mut stderr, "{}", e));
os::set_exit_status(1);
}
}