// Copyright 2015-2017 Parity Technologies (UK) Ltd. // This file is part of Parity. // Parity is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // Parity is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // You should have received a copy of the GNU General Public License // along with Parity. If not, see . use std::iter::repeat; use rand::{Rng, OsRng}; use ethkey::{Public, Secret, math}; use crypto; use util::Bytes; use jsonrpc_core::Error; use v1::helpers::errors; /// Initialization vector length. const INIT_VEC_LEN: usize = 16; /// Encrypt document with distributely generated key. pub fn encrypt_document(key: Bytes, document: Bytes) -> Result { // make document key let key = into_document_key(key)?; // use symmetric encryption to encrypt document let iv = initialization_vector(); let mut encrypted_document = Vec::with_capacity(document.len() + iv.len()); encrypted_document.extend(repeat(0).take(document.len())); crypto::aes::encrypt(&key, &iv, &document, &mut encrypted_document); encrypted_document.extend_from_slice(&iv); Ok(encrypted_document) } /// Decrypt document with distributely generated key. pub fn decrypt_document(key: Bytes, mut encrypted_document: Bytes) -> Result { // initialization vector takes INIT_VEC_LEN bytes let encrypted_document_len = encrypted_document.len(); if encrypted_document_len < INIT_VEC_LEN { return Err(errors::invalid_params("encrypted_document", "invalid encrypted data")); } // make document key let key = into_document_key(key)?; // use symmetric decryption to decrypt document let iv = encrypted_document.split_off(encrypted_document_len - INIT_VEC_LEN); let mut document = Vec::with_capacity(encrypted_document_len - INIT_VEC_LEN); document.extend(repeat(0).take(encrypted_document_len - INIT_VEC_LEN)); crypto::aes::decrypt(&key, &iv, &encrypted_document, &mut document); Ok(document) } pub fn decrypt_document_with_shadow(decrypted_secret: Public, common_point: Public, shadows: Vec, encrypted_document: Bytes) -> Result { let key = decrypt_with_shadow_coefficients(decrypted_secret, common_point, shadows)?; decrypt_document(key.to_vec(), encrypted_document) } fn into_document_key(key: Bytes) -> Result { // key is a previously distributely generated Public if key.len() != 64 { return Err(errors::invalid_params("key", "invalid public key length")); } // use x coordinate of distributely generated point as encryption key Ok(key[..INIT_VEC_LEN].into()) } fn initialization_vector() -> [u8; INIT_VEC_LEN] { let mut result = [0u8; INIT_VEC_LEN]; let mut rng = OsRng::new().unwrap(); rng.fill_bytes(&mut result); result } fn decrypt_with_shadow_coefficients(mut decrypted_shadow: Public, mut common_shadow_point: Public, shadow_coefficients: Vec) -> Result { let mut shadow_coefficients_sum = shadow_coefficients[0].clone(); for shadow_coefficient in shadow_coefficients.iter().skip(1) { shadow_coefficients_sum.add(shadow_coefficient) .map_err(errors::encryption)?; } math::public_mul_secret(&mut common_shadow_point, &shadow_coefficients_sum) .map_err(errors::encryption)?; math::public_add(&mut decrypted_shadow, &common_shadow_point) .map_err(errors::encryption)?; Ok(decrypted_shadow) } #[cfg(test)] mod tests { use util::Bytes; use rustc_serialize::hex::FromHex; use super::{encrypt_document, decrypt_document, decrypt_document_with_shadow}; #[test] fn encrypt_and_decrypt_document() { let document_key: Bytes = "cac6c205eb06c8308d65156ff6c862c62b000b8ead121a4455a8ddeff7248128d895692136f240d5d1614dc7cc4147b1bd584bd617e30560bb872064d09ea325".from_hex().unwrap(); let document: Bytes = b"Hello, world!!!"[..].into(); let encrypted_document = encrypt_document(document_key.clone(), document.clone()).unwrap(); assert!(document != encrypted_document); let decrypted_document = decrypt_document(document_key.clone(), encrypted_document).unwrap(); assert_eq!(decrypted_document, document); } #[test] fn encrypt_and_shadow_decrypt_document() { let document: Bytes = "deadbeef".from_hex().unwrap(); let encrypted_document = "2ddec1f96229efa2916988d8b2a82a47ef36f71c".from_hex().unwrap(); let decrypted_secret = "843645726384530ffb0c52f175278143b5a93959af7864460f5a4fec9afd1450cfb8aef63dec90657f43f55b13e0a73c7524d4e9a13c051b4e5f1e53f39ecd91".parse().unwrap(); let common_point = "07230e34ebfe41337d3ed53b186b3861751f2401ee74b988bba55694e2a6f60c757677e194be2e53c3523cc8548694e636e6acb35c4e8fdc5e29d28679b9b2f3".parse().unwrap(); let shadows = vec!["46f542416216f66a7d7881f5a283d2a1ab7a87b381cbc5f29d0b093c7c89ee31".parse().unwrap()]; let decrypted_document = decrypt_document_with_shadow(decrypted_secret, common_point, shadows, encrypted_document).unwrap(); assert_eq!(decrypted_document, document); } }