proxmox-backup/src/backup/crypt_config.rs

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//! Wrappers for OpenSSL crypto functions
//!
//! We use this to encrypt and decryprt data chunks. Cipher is
//! AES_256_GCM, which is fast and provides authenticated encryption.
//!
//! See the Wikipedia Artikel for [Authenticated
//! encryption](https://en.wikipedia.org/wiki/Authenticated_encryption)
//! for a short introduction.
use std::fmt;
use std::fmt::Display;
use std::io::Write;
use anyhow::{Error};
use openssl::hash::MessageDigest;
use openssl::pkcs5::pbkdf2_hmac;
use openssl::symm::{decrypt_aead, Cipher, Crypter, Mode};
use serde::{Deserialize, Serialize};
use crate::tools::format::{as_fingerprint, bytes_as_fingerprint};
use proxmox::api::api;
// openssl::sha::sha256(b"Proxmox Backup Encryption Key Fingerprint")
/// This constant is used to compute fingerprints.
const FINGERPRINT_INPUT: [u8; 32] = [
110, 208, 239, 119, 71, 31, 255, 77,
85, 199, 168, 254, 74, 157, 182, 33,
97, 64, 127, 19, 76, 114, 93, 223,
48, 153, 45, 37, 236, 69, 237, 38,
];
#[api(default: "encrypt")]
#[derive(Copy, Clone, Debug, Eq, PartialEq, Deserialize, Serialize)]
#[serde(rename_all = "kebab-case")]
/// Defines whether data is encrypted (using an AEAD cipher), only signed, or neither.
pub enum CryptMode {
/// Don't encrypt.
None,
/// Encrypt.
Encrypt,
/// Only sign.
SignOnly,
}
#[derive(Debug, Eq, PartialEq, Hash, Clone, Deserialize, Serialize)]
#[serde(transparent)]
/// 32-byte fingerprint, usually calculated with SHA256.
pub struct Fingerprint {
#[serde(with = "bytes_as_fingerprint")]
bytes: [u8; 32],
}
impl Fingerprint {
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pub fn new(bytes: [u8; 32]) -> Self {
Self { bytes }
}
pub fn bytes(&self) -> &[u8; 32] {
&self.bytes
}
}
/// Display as short key ID
impl Display for Fingerprint {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "{}", as_fingerprint(&self.bytes[0..8]))
}
}
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impl std::str::FromStr for Fingerprint {
type Err = Error;
fn from_str(s: &str) -> Result<Self, Error> {
let mut tmp = s.to_string();
tmp.retain(|c| c != ':');
let bytes = proxmox::tools::hex_to_digest(&tmp)?;
Ok(Fingerprint::new(bytes))
}
}
/// Encryption Configuration with secret key
///
/// This structure stores the secret key and provides helpers for
/// authenticated encryption.
pub struct CryptConfig {
// the Cipher
cipher: Cipher,
// A secrect key use to provide the chunk digest name space.
id_key: [u8; 32],
// Openssl hmac PKey of id_key
id_pkey: openssl::pkey::PKey<openssl::pkey::Private>,
// The private key used by the cipher.
enc_key: [u8; 32],
}
impl CryptConfig {
/// Create a new instance.
///
/// We compute a derived 32 byte key using pbkdf2_hmac. This second
/// key is used in compute_digest.
pub fn new(enc_key: [u8; 32]) -> Result<Self, Error> {
let mut id_key = [0u8; 32];
pbkdf2_hmac(
&enc_key,
b"_id_key",
10,
MessageDigest::sha256(),
&mut id_key)?;
let id_pkey = openssl::pkey::PKey::hmac(&id_key).unwrap();
Ok(Self { id_key, id_pkey, enc_key, cipher: Cipher::aes_256_gcm() })
}
/// Expose Cipher
pub fn cipher(&self) -> &Cipher {
&self.cipher
}
/// Compute a chunk digest using a secret name space.
///
/// Computes an SHA256 checksum over some secret data (derived
/// from the secret key) and the provided data. This ensures that
/// chunk digest values do not clash with values computed for
/// other sectret keys.
pub fn compute_digest(&self, data: &[u8]) -> [u8; 32] {
let mut hasher = openssl::sha::Sha256::new();
hasher.update(data);
hasher.update(&self.id_key); // at the end, to avoid length extensions attacks
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hasher.finish()
}
pub fn data_signer(&self) -> openssl::sign::Signer {
openssl::sign::Signer::new(MessageDigest::sha256(), &self.id_pkey).unwrap()
}
/// Compute authentication tag (hmac/sha256)
///
/// Computes an SHA256 HMAC using some secret data (derived
/// from the secret key) and the provided data.
pub fn compute_auth_tag(&self, data: &[u8]) -> [u8; 32] {
let mut signer = self.data_signer();
signer.update(data).unwrap();
let mut tag = [0u8; 32];
signer.sign(&mut tag).unwrap();
tag
}
pub fn fingerprint(&self) -> Fingerprint {
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Fingerprint::new(self.compute_digest(&FINGERPRINT_INPUT))
}
pub fn data_crypter(&self, iv: &[u8; 16], mode: Mode) -> Result<Crypter, Error> {
let mut crypter = openssl::symm::Crypter::new(self.cipher, mode, &self.enc_key, Some(iv))?;
crypter.aad_update(b"")?; //??
Ok(crypter)
}
/// Encrypt data using a random 16 byte IV.
///
/// Writes encrypted data to ``output``, Return the used IV and computed MAC.
pub fn encrypt_to<W: Write>(
&self,
data: &[u8],
mut output: W,
) -> Result<([u8;16], [u8;16]), Error> {
let mut iv = [0u8; 16];
proxmox::sys::linux::fill_with_random_data(&mut iv)?;
let mut tag = [0u8; 16];
let mut c = self.data_crypter(&iv, Mode::Encrypt)?;
const BUFFER_SIZE: usize = 32*1024;
let mut encr_buf = [0u8; BUFFER_SIZE];
let max_encoder_input = BUFFER_SIZE - self.cipher.block_size();
let mut start = 0;
loop {
let mut end = start + max_encoder_input;
if end > data.len() { end = data.len(); }
if end > start {
let count = c.update(&data[start..end], &mut encr_buf)?;
output.write_all(&encr_buf[..count])?;
start = end;
} else {
break;
}
}
let rest = c.finalize(&mut encr_buf)?;
if rest > 0 { output.write_all(&encr_buf[..rest])?; }
output.flush()?;
c.get_tag(&mut tag)?;
Ok((iv, tag))
}
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/// Decompress and decrypt data, verify MAC.
pub fn decode_compressed_chunk(
&self,
data: &[u8],
iv: &[u8; 16],
tag: &[u8; 16],
) -> Result<Vec<u8>, Error> {
let dec = Vec::with_capacity(1024*1024);
let mut decompressor = zstd::stream::write::Decoder::new(dec)?;
let mut c = self.data_crypter(iv, Mode::Decrypt)?;
const BUFFER_SIZE: usize = 32*1024;
let mut decr_buf = [0u8; BUFFER_SIZE];
let max_decoder_input = BUFFER_SIZE - self.cipher.block_size();
let mut start = 0;
loop {
let mut end = start + max_decoder_input;
if end > data.len() { end = data.len(); }
if end > start {
let count = c.update(&data[start..end], &mut decr_buf)?;
decompressor.write_all(&decr_buf[0..count])?;
start = end;
} else {
break;
}
}
c.set_tag(tag)?;
let rest = c.finalize(&mut decr_buf)?;
if rest > 0 { decompressor.write_all(&decr_buf[..rest])?; }
decompressor.flush()?;
Ok(decompressor.into_inner())
}
/// Decrypt data, verify tag.
pub fn decode_uncompressed_chunk(
&self,
data: &[u8],
iv: &[u8; 16],
tag: &[u8; 16],
) -> Result<Vec<u8>, Error> {
let decr_data = decrypt_aead(
self.cipher,
&self.enc_key,
Some(iv),
b"", //??
data,
tag,
)?;
Ok(decr_data)
}
}