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boring2/openssl/src/pkey.rs

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Rust
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use libc::{c_void, c_char, c_int, size_t};
use std::ptr;
use std::mem;
use std::ffi::CString;
use ffi;
use foreign_types::{ForeignType, ForeignTypeRef};
use {cvt, cvt_p};
use bio::MemBioSlice;
use dh::Dh;
use dsa::Dsa;
use ec::EcKey;
use rsa::{Rsa, Padding};
use error::ErrorStack;
use util::{CallbackState, invoke_passwd_cb, invoke_passwd_cb_old};
foreign_type_and_impl_send_sync! {
type CType = ffi::EVP_PKEY;
fn drop = ffi::EVP_PKEY_free;
pub struct PKey;
pub struct PKeyRef;
}
impl PKeyRef {
/// Returns a copy of the internal RSA key.
pub fn rsa(&self) -> Result<Rsa, ErrorStack> {
unsafe {
let rsa = cvt_p(ffi::EVP_PKEY_get1_RSA(self.as_ptr()))?;
Ok(Rsa::from_ptr(rsa))
}
}
/// Returns a copy of the internal DSA key.
pub fn dsa(&self) -> Result<Dsa, ErrorStack> {
unsafe {
let dsa = cvt_p(ffi::EVP_PKEY_get1_DSA(self.as_ptr()))?;
Ok(Dsa::from_ptr(dsa))
}
}
/// Returns a copy of the internal DH key.
pub fn dh(&self) -> Result<Dh, ErrorStack> {
unsafe {
let dh = cvt_p(ffi::EVP_PKEY_get1_DH(self.as_ptr()))?;
Ok(Dh::from_ptr(dh))
}
}
/// Returns a copy of the internal elliptic curve key.
pub fn ec_key(&self) -> Result<EcKey, ErrorStack> {
unsafe {
let ec_key = cvt_p(ffi::EVP_PKEY_get1_EC_KEY(self.as_ptr()))?;
Ok(EcKey::from_ptr(ec_key))
}
}
public_key_to_pem!(ffi::PEM_write_bio_PUBKEY);
private_key_to_pem!(ffi::PEM_write_bio_PKCS8PrivateKey);
private_key_to_der!(ffi::i2d_PrivateKey);
public_key_to_der!(ffi::i2d_PUBKEY);
/// Returns the size of the key.
///
/// This corresponds to the bit length of the modulus of an RSA key, and the bit length of the
/// group order for an elliptic curve key, for example.
pub fn bits(&self) -> u32 {
unsafe { ffi::EVP_PKEY_bits(self.as_ptr()) as u32 }
}
/// Compares the public component of this key with another.
pub fn public_eq(&self, other: &PKeyRef) -> bool {
unsafe { ffi::EVP_PKEY_cmp(self.as_ptr(), other.as_ptr()) == 1 }
}
}
impl PKey {
/// Creates a new `PKey` containing an RSA key.
pub fn from_rsa(rsa: Rsa) -> Result<PKey, ErrorStack> {
unsafe {
let evp = cvt_p(ffi::EVP_PKEY_new())?;
let pkey = PKey(evp);
cvt(ffi::EVP_PKEY_assign(
pkey.0,
ffi::EVP_PKEY_RSA,
rsa.as_ptr() as *mut _,
))?;
mem::forget(rsa);
Ok(pkey)
}
}
/// Creates a new `PKey` containing a DSA key.
pub fn from_dsa(dsa: Dsa) -> Result<PKey, ErrorStack> {
unsafe {
let evp = cvt_p(ffi::EVP_PKEY_new())?;
let pkey = PKey(evp);
cvt(ffi::EVP_PKEY_assign(
pkey.0,
ffi::EVP_PKEY_DSA,
dsa.as_ptr() as *mut _,
))?;
mem::forget(dsa);
Ok(pkey)
}
}
/// Creates a new `PKey` containing a Diffie-Hellman key.
pub fn from_dh(dh: Dh) -> Result<PKey, ErrorStack> {
unsafe {
let evp = cvt_p(ffi::EVP_PKEY_new())?;
let pkey = PKey(evp);
cvt(ffi::EVP_PKEY_assign(
pkey.0,
ffi::EVP_PKEY_DH,
dh.as_ptr() as *mut _,
))?;
mem::forget(dh);
Ok(pkey)
}
}
/// Creates a new `PKey` containing an elliptic curve key.
pub fn from_ec_key(ec_key: EcKey) -> Result<PKey, ErrorStack> {
unsafe {
let evp = cvt_p(ffi::EVP_PKEY_new())?;
let pkey = PKey(evp);
cvt(ffi::EVP_PKEY_assign(
pkey.0,
ffi::EVP_PKEY_EC,
ec_key.as_ptr() as *mut _,
))?;
mem::forget(ec_key);
Ok(pkey)
}
}
/// Creates a new `PKey` containing an HMAC key.
///
/// # Note
/// To compute HMAC values, use the `sign` module.
pub fn hmac(key: &[u8]) -> Result<PKey, ErrorStack> {
unsafe {
assert!(key.len() <= c_int::max_value() as usize);
let key = cvt_p(ffi::EVP_PKEY_new_mac_key(
ffi::EVP_PKEY_HMAC,
ptr::null_mut(),
key.as_ptr() as *const _,
key.len() as c_int,
))?;
Ok(PKey(key))
}
}
private_key_from_pem!(PKey, ffi::PEM_read_bio_PrivateKey);
public_key_from_pem!(PKey, ffi::PEM_read_bio_PUBKEY);
public_key_from_der!(PKey, ffi::d2i_PUBKEY);
private_key_from_der!(PKey, ffi::d2i_AutoPrivateKey);
/// Deserializes a DER-formatted PKCS#8 private key, using a callback to retrieve the password
/// if the key is encrpyted.
///
/// The callback should copy the password into the provided buffer and return the number of
/// bytes written.
pub fn private_key_from_pkcs8_callback<F>(der: &[u8], callback: F) -> Result<PKey, ErrorStack>
where
F: FnOnce(&mut [u8]) -> Result<usize, ErrorStack>,
{
unsafe {
ffi::init();
let mut cb = CallbackState::new(callback);
let bio = MemBioSlice::new(der)?;
cvt_p(ffi::d2i_PKCS8PrivateKey_bio(
bio.as_ptr(),
ptr::null_mut(),
Some(invoke_passwd_cb::<F>),
&mut cb as *mut _ as *mut _,
)).map(PKey)
}
}
/// Deserializes a DER-formatted PKCS#8 private key, using the supplied password if the key is
/// encrypted.
///
/// # Panics
///
/// Panics if `passphrase` contains an embedded null.
pub fn private_key_from_pkcs8_passphrase(
der: &[u8],
passphrase: &[u8],
) -> Result<PKey, ErrorStack> {
unsafe {
ffi::init();
let bio = MemBioSlice::new(der)?;
let passphrase = CString::new(passphrase).unwrap();
cvt_p(ffi::d2i_PKCS8PrivateKey_bio(
bio.as_ptr(),
ptr::null_mut(),
None,
passphrase.as_ptr() as *const _ as *mut _,
)).map(PKey)
}
}
#[deprecated(since = "0.9.2", note = "use private_key_from_pem_callback")]
pub fn private_key_from_pem_cb<F>(buf: &[u8], pass_cb: F) -> Result<PKey, ErrorStack>
where
F: FnOnce(&mut [c_char]) -> usize,
{
ffi::init();
let mut cb = CallbackState::new(pass_cb);
let mem_bio = MemBioSlice::new(buf)?;
unsafe {
let evp = cvt_p(ffi::PEM_read_bio_PrivateKey(
mem_bio.as_ptr(),
ptr::null_mut(),
Some(invoke_passwd_cb_old::<F>),
&mut cb as *mut _ as *mut c_void,
))?;
Ok(PKey::from_ptr(evp))
}
}
}
foreign_type_and_impl_send_sync! {
type CType = ffi::EVP_PKEY_CTX;
fn drop = ffi::EVP_PKEY_CTX_free;
pub struct PKeyCtx;
pub struct PKeyCtxRef;
}
impl PKeyCtx {
pub fn from_pkey(pkey: &PKeyRef) -> Result<PKeyCtx, ErrorStack> {
unsafe {
let evp = cvt_p(ffi::EVP_PKEY_CTX_new(pkey.as_ptr(), ptr::null_mut()))?;
Ok(PKeyCtx(evp))
}
}
}
impl PKeyCtxRef {
pub fn set_rsa_padding(&mut self, pad: Padding) -> Result<(), ErrorStack> {
unsafe {
cvt(ffi::EVP_PKEY_CTX_set_rsa_padding(
self.as_ptr(),
pad.as_raw(),
))?;
}
Ok(())
}
pub fn rsa_padding(&self) -> Result<Padding, ErrorStack> {
let mut pad: c_int = 0;
unsafe {
cvt(
ffi::EVP_PKEY_CTX_get_rsa_padding(self.as_ptr(), &mut pad),
)?;
};
Ok(Padding::from_raw(pad))
}
pub fn derive_init(&mut self) -> Result<(), ErrorStack> {
unsafe {
cvt(ffi::EVP_PKEY_derive_init(self.as_ptr()))?;
}
Ok(())
}
pub fn derive_set_peer(&mut self, peer: &PKeyRef) -> Result<(), ErrorStack> {
unsafe {
cvt(
ffi::EVP_PKEY_derive_set_peer(self.as_ptr(), peer.as_ptr()),
)?;
}
Ok(())
}
pub fn derive(&mut self) -> Result<Vec<u8>, ErrorStack> {
let mut len: size_t = 0;
unsafe {
cvt(ffi::EVP_PKEY_derive(
self.as_ptr(),
ptr::null_mut(),
&mut len,
))?;
}
let mut key = vec![0u8; len];
unsafe {
cvt(ffi::EVP_PKEY_derive(
self.as_ptr(),
key.as_mut_ptr(),
&mut len,
))?;
}
Ok(key)
}
}
#[cfg(test)]
mod tests {
use symm::Cipher;
use dh::Dh;
use dsa::Dsa;
use ec::{EcGroup, EcKey};
use rsa::Rsa;
use nid;
use super::*;
#[test]
fn test_to_password() {
let rsa = Rsa::generate(2048).unwrap();
let pkey = PKey::from_rsa(rsa).unwrap();
let pem = pkey.private_key_to_pem_passphrase(Cipher::aes_128_cbc(), b"foobar")
.unwrap();
PKey::private_key_from_pem_passphrase(&pem, b"foobar").unwrap();
assert!(PKey::private_key_from_pem_passphrase(&pem, b"fizzbuzz").is_err());
}
#[test]
fn test_encrypted_pkcs8_passphrase() {
let key = include_bytes!("../test/pkcs8.der");
PKey::private_key_from_pkcs8_passphrase(key, b"mypass").unwrap();
}
#[test]
fn test_encrypted_pkcs8_callback() {
let mut password_queried = false;
let key = include_bytes!("../test/pkcs8.der");
PKey::private_key_from_pkcs8_callback(key, |password| {
password_queried = true;
password[..6].copy_from_slice(b"mypass");
Ok(6)
}).unwrap();
assert!(password_queried);
}
#[test]
fn test_private_key_from_pem() {
let key = include_bytes!("../test/key.pem");
PKey::private_key_from_pem(key).unwrap();
}
#[test]
fn test_public_key_from_pem() {
let key = include_bytes!("../test/key.pem.pub");
PKey::public_key_from_pem(key).unwrap();
}
#[test]
fn test_public_key_from_der() {
let key = include_bytes!("../test/key.der.pub");
PKey::public_key_from_der(key).unwrap();
}
#[test]
fn test_private_key_from_der() {
let key = include_bytes!("../test/key.der");
PKey::private_key_from_der(key).unwrap();
}
#[test]
fn test_pem() {
let key = include_bytes!("../test/key.pem");
let key = PKey::private_key_from_pem(key).unwrap();
let priv_key = key.private_key_to_pem().unwrap();
let pub_key = key.public_key_to_pem().unwrap();
// As a super-simple verification, just check that the buffers contain
// the `PRIVATE KEY` or `PUBLIC KEY` strings.
assert!(priv_key.windows(11).any(|s| s == b"PRIVATE KEY"));
assert!(pub_key.windows(10).any(|s| s == b"PUBLIC KEY"));
}
#[test]
fn test_rsa_accessor() {
let rsa = Rsa::generate(2048).unwrap();
let pkey = PKey::from_rsa(rsa).unwrap();
pkey.rsa().unwrap();
assert!(pkey.dsa().is_err());
}
#[test]
fn test_dsa_accessor() {
let dsa = Dsa::generate(2048).unwrap();
let pkey = PKey::from_dsa(dsa).unwrap();
pkey.dsa().unwrap();
assert!(pkey.rsa().is_err());
}
#[test]
fn test_dh_accessor() {
let dh = include_bytes!("../test/dhparams.pem");
let dh = Dh::from_pem(dh).unwrap();
let pkey = PKey::from_dh(dh).unwrap();
pkey.dh().unwrap();
assert!(pkey.rsa().is_err());
}
#[test]
fn test_ec_key_accessor() {
let ec_key = EcKey::from_curve_name(nid::X9_62_PRIME256V1).unwrap();
let pkey = PKey::from_ec_key(ec_key).unwrap();
pkey.ec_key().unwrap();
assert!(pkey.rsa().is_err());
}
#[test]
fn test_ec_key_derive() {
let group = EcGroup::from_curve_name(nid::X9_62_PRIME256V1).unwrap();
let ec_key = EcKey::generate(&group).unwrap();
let ec_key2 = EcKey::generate(&group).unwrap();
let pkey = PKey::from_ec_key(ec_key).unwrap();
let pkey2 = PKey::from_ec_key(ec_key2).unwrap();
let mut pkey_ctx = PKeyCtx::from_pkey(&pkey).unwrap();
pkey_ctx.derive_init().unwrap();
pkey_ctx.derive_set_peer(&pkey2).unwrap();
let shared = pkey_ctx.derive().unwrap();
assert!(!shared.is_empty());
}
}
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