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//! Rivest–Shamir–Adleman cryptosystem
//!
//! RSA is one of the earliest asymmetric public key encryption schemes.
//! Like many other cryptosystems, RSA relies on the presumed difficulty of a hard
//! mathematical problem, namely factorization of the product of two large prime
//! numbers. At the moment there does not exist an algorithm that can factor such
//! large numbers in reasonable time. RSA is used in a wide variety of
//! applications including digital signatures and key exchanges such as
//! establishing a TLS/SSL connection.
//!
//! The RSA acronym is derived from the first letters of the surnames of the
//! algorithm's founding trio.
//!
//! # Example
//!
//! Generate a 2048-bit RSA key pair and use the public key to encrypt some data.
//!
//! ```rust
//! use openssl::rsa::{Rsa, Padding};
//!
//! let rsa = Rsa::generate(2048).unwrap();
//! let data = b"foobar";
//! let mut buf = vec![0; rsa.size() as usize];
//! let encrypted_len = rsa.public_encrypt(data, &mut buf, Padding::PKCS1).unwrap();
//! ```
use cfg_if::cfg_if;
use foreign_types::{ForeignType, ForeignTypeRef};
use libc::c_int;
use std::fmt;
use std::mem;
use std::ptr;
use crate::bn::{BigNum, BigNumRef};
use crate::error::ErrorStack;
use crate::pkey::{HasPrivate, HasPublic, Private, Public};
use crate::util::ForeignTypeRefExt;
use crate::{cvt, cvt_n, cvt_p, LenType};
use openssl_macros::corresponds;
/// Type of encryption padding to use.
///
/// Random length padding is primarily used to prevent attackers from
/// predicting or knowing the exact length of a plaintext message that
/// can possibly lead to breaking encryption.
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
pub struct Padding(c_int);
impl Padding {
pub const NONE: Padding = Padding(ffi::RSA_NO_PADDING);
pub const PKCS1: Padding = Padding(ffi::RSA_PKCS1_PADDING);
pub const PKCS1_OAEP: Padding = Padding(ffi::RSA_PKCS1_OAEP_PADDING);
pub const PKCS1_PSS: Padding = Padding(ffi::RSA_PKCS1_PSS_PADDING);
/// Creates a `Padding` from an integer representation.
pub fn from_raw(value: c_int) -> Padding {
Padding(value)
}
/// Returns the integer representation of `Padding`.
#[allow(clippy::trivially_copy_pass_by_ref)]
pub fn as_raw(&self) -> c_int {
self.0
}
}
generic_foreign_type_and_impl_send_sync! {
type CType = ffi::RSA;
fn drop = ffi::RSA_free;
/// An RSA key.
pub struct Rsa<T>;
/// Reference to `RSA`
pub struct RsaRef<T>;
}
impl<T> Clone for Rsa<T> {
fn clone(&self) -> Rsa<T> {
(**self).to_owned()
}
}
impl<T> ToOwned for RsaRef<T> {
type Owned = Rsa<T>;
fn to_owned(&self) -> Rsa<T> {
unsafe {
ffi::RSA_up_ref(self.as_ptr());
Rsa::from_ptr(self.as_ptr())
}
}
}
impl<T> RsaRef<T>
where
T: HasPrivate,
{
private_key_to_pem! {
/// Serializes the private key to a PEM-encoded PKCS#1 RSAPrivateKey structure.
///
/// The output will have a header of `-----BEGIN RSA PRIVATE KEY-----`.
#[corresponds(PEM_write_bio_RSAPrivateKey)]
private_key_to_pem,
/// Serializes the private key to a PEM-encoded encrypted PKCS#1 RSAPrivateKey structure.
///
/// The output will have a header of `-----BEGIN RSA PRIVATE KEY-----`.
#[corresponds(PEM_write_bio_RSAPrivateKey)]
private_key_to_pem_passphrase,
ffi::PEM_write_bio_RSAPrivateKey
}
to_der! {
/// Serializes the private key to a DER-encoded PKCS#1 RSAPrivateKey structure.
#[corresponds(i2d_RSAPrivateKey)]
private_key_to_der,
ffi::i2d_RSAPrivateKey
}
/// Decrypts data using the private key, returning the number of decrypted bytes.
///
/// # Panics
///
/// Panics if `self` has no private components, or if `to` is smaller
/// than `self.size()`.
#[corresponds(RSA_private_decrypt)]
pub fn private_decrypt(
&self,
from: &[u8],
to: &mut [u8],
padding: Padding,
) -> Result<usize, ErrorStack> {
assert!(from.len() <= i32::max_value() as usize);
assert!(to.len() >= self.size() as usize);
unsafe {
let len = cvt_n(ffi::RSA_private_decrypt(
from.len() as LenType,
from.as_ptr(),
to.as_mut_ptr(),
self.as_ptr(),
padding.0,
))?;
Ok(len as usize)
}
}
/// Encrypts data using the private key, returning the number of encrypted bytes.
///
/// # Panics
///
/// Panics if `self` has no private components, or if `to` is smaller
/// than `self.size()`.
#[corresponds(RSA_private_encrypt)]
pub fn private_encrypt(
&self,
from: &[u8],
to: &mut [u8],
padding: Padding,
) -> Result<usize, ErrorStack> {
assert!(from.len() <= i32::max_value() as usize);
assert!(to.len() >= self.size() as usize);
unsafe {
let len = cvt_n(ffi::RSA_private_encrypt(
from.len() as LenType,
from.as_ptr(),
to.as_mut_ptr(),
self.as_ptr(),
padding.0,
))?;
Ok(len as usize)
}
}
/// Returns a reference to the private exponent of the key.
#[corresponds(RSA_get0_key)]
pub fn d(&self) -> &BigNumRef {
unsafe {
let mut d = ptr::null();
RSA_get0_key(self.as_ptr(), ptr::null_mut(), ptr::null_mut(), &mut d);
BigNumRef::from_const_ptr(d)
}
}
/// Returns a reference to the first factor of the exponent of the key.
#[corresponds(RSA_get0_factors)]
pub fn p(&self) -> Option<&BigNumRef> {
unsafe {
let mut p = ptr::null();
RSA_get0_factors(self.as_ptr(), &mut p, ptr::null_mut());
BigNumRef::from_const_ptr_opt(p)
}
}
/// Returns a reference to the second factor of the exponent of the key.
#[corresponds(RSA_get0_factors)]
pub fn q(&self) -> Option<&BigNumRef> {
unsafe {
let mut q = ptr::null();
RSA_get0_factors(self.as_ptr(), ptr::null_mut(), &mut q);
BigNumRef::from_const_ptr_opt(q)
}
}
/// Returns a reference to the first exponent used for CRT calculations.
#[corresponds(RSA_get0_crt_params)]
pub fn dmp1(&self) -> Option<&BigNumRef> {
unsafe {
let mut dp = ptr::null();
RSA_get0_crt_params(self.as_ptr(), &mut dp, ptr::null_mut(), ptr::null_mut());
BigNumRef::from_const_ptr_opt(dp)
}
}
/// Returns a reference to the second exponent used for CRT calculations.
#[corresponds(RSA_get0_crt_params)]
pub fn dmq1(&self) -> Option<&BigNumRef> {
unsafe {
let mut dq = ptr::null();
RSA_get0_crt_params(self.as_ptr(), ptr::null_mut(), &mut dq, ptr::null_mut());
BigNumRef::from_const_ptr_opt(dq)
}
}
/// Returns a reference to the coefficient used for CRT calculations.
#[corresponds(RSA_get0_crt_params)]
pub fn iqmp(&self) -> Option<&BigNumRef> {
unsafe {
let mut qi = ptr::null();
RSA_get0_crt_params(self.as_ptr(), ptr::null_mut(), ptr::null_mut(), &mut qi);
BigNumRef::from_const_ptr_opt(qi)
}
}
/// Validates RSA parameters for correctness
#[corresponds(RSA_check_key)]
#[allow(clippy::unnecessary_cast)]
pub fn check_key(&self) -> Result<bool, ErrorStack> {
unsafe {
let result = ffi::RSA_check_key(self.as_ptr()) as i32;
if result == -1 {
Err(ErrorStack::get())
} else {
Ok(result == 1)
}
}
}
}
impl<T> RsaRef<T>
where
T: HasPublic,
{
to_pem! {
/// Serializes the public key into a PEM-encoded SubjectPublicKeyInfo structure.
///
/// The output will have a header of `-----BEGIN PUBLIC KEY-----`.
#[corresponds(PEM_write_bio_RSA_PUBKEY)]
public_key_to_pem,
ffi::PEM_write_bio_RSA_PUBKEY
}
to_der! {
/// Serializes the public key into a DER-encoded SubjectPublicKeyInfo structure.
#[corresponds(i2d_RSA_PUBKEY)]
public_key_to_der,
ffi::i2d_RSA_PUBKEY
}
to_pem! {
/// Serializes the public key into a PEM-encoded PKCS#1 RSAPublicKey structure.
///
/// The output will have a header of `-----BEGIN RSA PUBLIC KEY-----`.
#[corresponds(PEM_write_bio_RSAPublicKey)]
public_key_to_pem_pkcs1,
ffi::PEM_write_bio_RSAPublicKey
}
to_der! {
/// Serializes the public key into a DER-encoded PKCS#1 RSAPublicKey structure.
#[corresponds(i2d_RSAPublicKey)]
public_key_to_der_pkcs1,
ffi::i2d_RSAPublicKey
}
/// Returns the size of the modulus in bytes.
#[corresponds(RSA_size)]
pub fn size(&self) -> u32 {
unsafe { ffi::RSA_size(self.as_ptr()) as u32 }
}
/// Decrypts data using the public key, returning the number of decrypted bytes.
///
/// # Panics
///
/// Panics if `to` is smaller than `self.size()`.
#[corresponds(RSA_public_decrypt)]
pub fn public_decrypt(
&self,
from: &[u8],
to: &mut [u8],
padding: Padding,
) -> Result<usize, ErrorStack> {
assert!(from.len() <= i32::max_value() as usize);
assert!(to.len() >= self.size() as usize);
unsafe {
let len = cvt_n(ffi::RSA_public_decrypt(
from.len() as LenType,
from.as_ptr(),
to.as_mut_ptr(),
self.as_ptr(),
padding.0,
))?;
Ok(len as usize)
}
}
/// Encrypts data using the public key, returning the number of encrypted bytes.
///
/// # Panics
///
/// Panics if `to` is smaller than `self.size()`.
#[corresponds(RSA_public_encrypt)]
pub fn public_encrypt(
&self,
from: &[u8],
to: &mut [u8],
padding: Padding,
) -> Result<usize, ErrorStack> {
assert!(from.len() <= i32::max_value() as usize);
assert!(to.len() >= self.size() as usize);
unsafe {
let len = cvt_n(ffi::RSA_public_encrypt(
from.len() as LenType,
from.as_ptr(),
to.as_mut_ptr(),
self.as_ptr(),
padding.0,
))?;
Ok(len as usize)
}
}
/// Returns a reference to the modulus of the key.
#[corresponds(RSA_get0_key)]
pub fn n(&self) -> &BigNumRef {
unsafe {
let mut n = ptr::null();
RSA_get0_key(self.as_ptr(), &mut n, ptr::null_mut(), ptr::null_mut());
BigNumRef::from_const_ptr(n)
}
}
/// Returns a reference to the public exponent of the key.
#[corresponds(RSA_get0_key)]
pub fn e(&self) -> &BigNumRef {
unsafe {
let mut e = ptr::null();
RSA_get0_key(self.as_ptr(), ptr::null_mut(), &mut e, ptr::null_mut());
BigNumRef::from_const_ptr(e)
}
}
}
impl Rsa<Public> {
/// Creates a new RSA key with only public components.
///
/// `n` is the modulus common to both public and private key.
/// `e` is the public exponent.
///
/// This corresponds to [`RSA_new`] and uses [`RSA_set0_key`].
///
/// [`RSA_new`]: https://www.openssl.org/docs/manmaster/crypto/RSA_new.html
/// [`RSA_set0_key`]: https://www.openssl.org/docs/manmaster/crypto/RSA_set0_key.html
pub fn from_public_components(n: BigNum, e: BigNum) -> Result<Rsa<Public>, ErrorStack> {
unsafe {
let rsa = cvt_p(ffi::RSA_new())?;
RSA_set0_key(rsa, n.as_ptr(), e.as_ptr(), ptr::null_mut());
mem::forget((n, e));
Ok(Rsa::from_ptr(rsa))
}
}
from_pem! {
/// Decodes a PEM-encoded SubjectPublicKeyInfo structure containing an RSA key.
///
/// The input should have a header of `-----BEGIN PUBLIC KEY-----`.
#[corresponds(PEM_read_bio_RSA_PUBKEY)]
public_key_from_pem,
Rsa<Public>,
ffi::PEM_read_bio_RSA_PUBKEY
}
from_pem! {
/// Decodes a PEM-encoded PKCS#1 RSAPublicKey structure.
///
/// The input should have a header of `-----BEGIN RSA PUBLIC KEY-----`.
#[corresponds(PEM_read_bio_RSAPublicKey)]
public_key_from_pem_pkcs1,
Rsa<Public>,
ffi::PEM_read_bio_RSAPublicKey
}
from_der! {
/// Decodes a DER-encoded SubjectPublicKeyInfo structure containing an RSA key.
#[corresponds(d2i_RSA_PUBKEY)]
public_key_from_der,
Rsa<Public>,
ffi::d2i_RSA_PUBKEY
}
from_der! {
/// Decodes a DER-encoded PKCS#1 RSAPublicKey structure.
#[corresponds(d2i_RSAPublicKey)]
public_key_from_der_pkcs1,
Rsa<Public>,
ffi::d2i_RSAPublicKey
}
}
pub struct RsaPrivateKeyBuilder {
rsa: Rsa<Private>,
}
impl RsaPrivateKeyBuilder {
/// Creates a new `RsaPrivateKeyBuilder`.
///
/// `n` is the modulus common to both public and private key.
/// `e` is the public exponent and `d` is the private exponent.
///
/// This corresponds to [`RSA_new`] and uses [`RSA_set0_key`].
///
/// [`RSA_new`]: https://www.openssl.org/docs/manmaster/crypto/RSA_new.html
/// [`RSA_set0_key`]: https://www.openssl.org/docs/manmaster/crypto/RSA_set0_key.html
pub fn new(n: BigNum, e: BigNum, d: BigNum) -> Result<RsaPrivateKeyBuilder, ErrorStack> {
unsafe {
let rsa = cvt_p(ffi::RSA_new())?;
RSA_set0_key(rsa, n.as_ptr(), e.as_ptr(), d.as_ptr());
mem::forget((n, e, d));
Ok(RsaPrivateKeyBuilder {
rsa: Rsa::from_ptr(rsa),
})
}
}
/// Sets the factors of the Rsa key.
///
/// `p` and `q` are the first and second factors of `n`.
#[corresponds(RSA_set0_factors)]
// FIXME should be infallible
pub fn set_factors(self, p: BigNum, q: BigNum) -> Result<RsaPrivateKeyBuilder, ErrorStack> {
unsafe {
RSA_set0_factors(self.rsa.as_ptr(), p.as_ptr(), q.as_ptr());
mem::forget((p, q));
}
Ok(self)
}
/// Sets the Chinese Remainder Theorem params of the Rsa key.
///
/// `dmp1`, `dmq1`, and `iqmp` are the exponents and coefficient for
/// CRT calculations which is used to speed up RSA operations.
#[corresponds(RSA_set0_crt_params)]
// FIXME should be infallible
pub fn set_crt_params(
self,
dmp1: BigNum,
dmq1: BigNum,
iqmp: BigNum,
) -> Result<RsaPrivateKeyBuilder, ErrorStack> {
unsafe {
RSA_set0_crt_params(
self.rsa.as_ptr(),
dmp1.as_ptr(),
dmq1.as_ptr(),
iqmp.as_ptr(),
);
mem::forget((dmp1, dmq1, iqmp));
}
Ok(self)
}
/// Returns the Rsa key.
pub fn build(self) -> Rsa<Private> {
self.rsa
}
}
impl Rsa<Private> {
/// Creates a new RSA key with private components (public components are assumed).
///
/// This a convenience method over:
/// ```
/// # use openssl::rsa::RsaPrivateKeyBuilder;
/// # fn main() -> Result<(), Box<dyn std::error::Error>> {
/// # let bn = || openssl::bn::BigNum::new().unwrap();
/// # let (n, e, d, p, q, dmp1, dmq1, iqmp) = (bn(), bn(), bn(), bn(), bn(), bn(), bn(), bn());
/// RsaPrivateKeyBuilder::new(n, e, d)?
/// .set_factors(p, q)?
/// .set_crt_params(dmp1, dmq1, iqmp)?
/// .build();
/// # Ok(()) }
/// ```
#[allow(clippy::too_many_arguments, clippy::many_single_char_names)]
pub fn from_private_components(
n: BigNum,
e: BigNum,
d: BigNum,
p: BigNum,
q: BigNum,
dmp1: BigNum,
dmq1: BigNum,
iqmp: BigNum,
) -> Result<Rsa<Private>, ErrorStack> {
Ok(RsaPrivateKeyBuilder::new(n, e, d)?
.set_factors(p, q)?
.set_crt_params(dmp1, dmq1, iqmp)?
.build())
}
/// Generates a public/private key pair with the specified size.
///
/// The public exponent will be 65537.
#[corresponds(RSA_generate_key_ex)]
pub fn generate(bits: u32) -> Result<Rsa<Private>, ErrorStack> {
let e = BigNum::from_u32(ffi::RSA_F4 as u32)?;
Rsa::generate_with_e(bits, &e)
}
/// Generates a public/private key pair with the specified size and a custom exponent.
///
/// Unless you have specific needs and know what you're doing, use `Rsa::generate` instead.
#[corresponds(RSA_generate_key_ex)]
pub fn generate_with_e(bits: u32, e: &BigNumRef) -> Result<Rsa<Private>, ErrorStack> {
unsafe {
let rsa = Rsa::from_ptr(cvt_p(ffi::RSA_new())?);
cvt(ffi::RSA_generate_key_ex(
rsa.0,
bits as c_int,
e.as_ptr(),
ptr::null_mut(),
))?;
Ok(rsa)
}
}
// FIXME these need to identify input formats
private_key_from_pem! {
/// Deserializes a private key from a PEM-encoded PKCS#1 RSAPrivateKey structure.
#[corresponds(PEM_read_bio_RSAPrivateKey)]
private_key_from_pem,
/// Deserializes a private key from a PEM-encoded encrypted PKCS#1 RSAPrivateKey structure.
#[corresponds(PEM_read_bio_RSAPrivateKey)]
private_key_from_pem_passphrase,
/// Deserializes a private key from a PEM-encoded encrypted PKCS#1 RSAPrivateKey structure.
///
/// The callback should fill the password into the provided buffer and return its length.
#[corresponds(PEM_read_bio_RSAPrivateKey)]
private_key_from_pem_callback,
Rsa<Private>,
ffi::PEM_read_bio_RSAPrivateKey
}
from_der! {
/// Decodes a DER-encoded PKCS#1 RSAPrivateKey structure.
#[corresponds(d2i_RSAPrivateKey)]
private_key_from_der,
Rsa<Private>,
ffi::d2i_RSAPrivateKey
}
}
impl<T> fmt::Debug for Rsa<T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "Rsa")
}
}
cfg_if! {
if #[cfg(any(ossl110, libressl273, boringssl))] {
use ffi::{
RSA_get0_key, RSA_get0_factors, RSA_get0_crt_params, RSA_set0_key, RSA_set0_factors,
RSA_set0_crt_params,
};
} else {
#[allow(bad_style)]
unsafe fn RSA_get0_key(
r: *const ffi::RSA,
n: *mut *const ffi::BIGNUM,
e: *mut *const ffi::BIGNUM,
d: *mut *const ffi::BIGNUM,
) {
if !n.is_null() {
*n = (*r).n;
}
if !e.is_null() {
*e = (*r).e;
}
if !d.is_null() {
*d = (*r).d;
}
}
#[allow(bad_style)]
unsafe fn RSA_get0_factors(
r: *const ffi::RSA,
p: *mut *const ffi::BIGNUM,
q: *mut *const ffi::BIGNUM,
) {
if !p.is_null() {
*p = (*r).p;
}
if !q.is_null() {
*q = (*r).q;
}
}
#[allow(bad_style)]
unsafe fn RSA_get0_crt_params(
r: *const ffi::RSA,
dmp1: *mut *const ffi::BIGNUM,
dmq1: *mut *const ffi::BIGNUM,
iqmp: *mut *const ffi::BIGNUM,
) {
if !dmp1.is_null() {
*dmp1 = (*r).dmp1;
}
if !dmq1.is_null() {
*dmq1 = (*r).dmq1;
}
if !iqmp.is_null() {
*iqmp = (*r).iqmp;
}
}
#[allow(bad_style)]
unsafe fn RSA_set0_key(
r: *mut ffi::RSA,
n: *mut ffi::BIGNUM,
e: *mut ffi::BIGNUM,
d: *mut ffi::BIGNUM,
) -> c_int {
(*r).n = n;
(*r).e = e;
(*r).d = d;
1
}
#[allow(bad_style)]
unsafe fn RSA_set0_factors(
r: *mut ffi::RSA,
p: *mut ffi::BIGNUM,
q: *mut ffi::BIGNUM,
) -> c_int {
(*r).p = p;
(*r).q = q;
1
}
#[allow(bad_style)]
unsafe fn RSA_set0_crt_params(
r: *mut ffi::RSA,
dmp1: *mut ffi::BIGNUM,
dmq1: *mut ffi::BIGNUM,
iqmp: *mut ffi::BIGNUM,
) -> c_int {
(*r).dmp1 = dmp1;
(*r).dmq1 = dmq1;
(*r).iqmp = iqmp;
1
}
}
}
#[cfg(test)]
mod test {
use crate::symm::Cipher;
use super::*;
#[test]
fn test_from_password() {
let key = include_bytes!("../test/rsa-encrypted.pem");
Rsa::private_key_from_pem_passphrase(key, b"mypass").unwrap();
}
#[test]
fn test_from_password_callback() {
let mut password_queried = false;
let key = include_bytes!("../test/rsa-encrypted.pem");
Rsa::private_key_from_pem_callback(key, |password| {
password_queried = true;
password[..6].copy_from_slice(b"mypass");
Ok(6)
})
.unwrap();
assert!(password_queried);
}
#[test]
fn test_to_password() {
let key = Rsa::generate(2048).unwrap();
let pem = key
.private_key_to_pem_passphrase(Cipher::aes_128_cbc(), b"foobar")
.unwrap();
Rsa::private_key_from_pem_passphrase(&pem, b"foobar").unwrap();
assert!(Rsa::private_key_from_pem_passphrase(&pem, b"fizzbuzz").is_err());
}
#[test]
fn test_public_encrypt_private_decrypt_with_padding() {
let key = include_bytes!("../test/rsa.pem.pub");
let public_key = Rsa::public_key_from_pem(key).unwrap();
let mut result = vec![0; public_key.size() as usize];
let original_data = b"This is test";
let len = public_key
.public_encrypt(original_data, &mut result, Padding::PKCS1)
.unwrap();
assert_eq!(len, 256);
let pkey = include_bytes!("../test/rsa.pem");
let private_key = Rsa::private_key_from_pem(pkey).unwrap();
let mut dec_result = vec![0; private_key.size() as usize];
let len = private_key
.private_decrypt(&result, &mut dec_result, Padding::PKCS1)
.unwrap();
assert_eq!(&dec_result[..len], original_data);
}
#[test]
fn test_private_encrypt() {
let k0 = super::Rsa::generate(512).unwrap();
let k0pkey = k0.public_key_to_pem().unwrap();
let k1 = super::Rsa::public_key_from_pem(&k0pkey).unwrap();
let msg = vec![0xdeu8, 0xadu8, 0xd0u8, 0x0du8];
let mut emesg = vec![0; k0.size() as usize];
k0.private_encrypt(&msg, &mut emesg, Padding::PKCS1)
.unwrap();
let mut dmesg = vec![0; k1.size() as usize];
let len = k1
.public_decrypt(&emesg, &mut dmesg, Padding::PKCS1)
.unwrap();
assert_eq!(msg, &dmesg[..len]);
}
#[test]
fn test_public_encrypt() {
let k0 = super::Rsa::generate(512).unwrap();
let k0pkey = k0.private_key_to_pem().unwrap();
let k1 = super::Rsa::private_key_from_pem(&k0pkey).unwrap();
let msg = vec![0xdeu8, 0xadu8, 0xd0u8, 0x0du8];
let mut emesg = vec![0; k0.size() as usize];
k0.public_encrypt(&msg, &mut emesg, Padding::PKCS1).unwrap();
let mut dmesg = vec![0; k1.size() as usize];
let len = k1
.private_decrypt(&emesg, &mut dmesg, Padding::PKCS1)
.unwrap();
assert_eq!(msg, &dmesg[..len]);
}
#[test]
fn test_public_key_from_pem_pkcs1() {
let key = include_bytes!("../test/pkcs1.pem.pub");
Rsa::public_key_from_pem_pkcs1(key).unwrap();
}
#[test]
#[should_panic]
fn test_public_key_from_pem_pkcs1_file_panic() {
let key = include_bytes!("../test/key.pem.pub");
Rsa::public_key_from_pem_pkcs1(key).unwrap();
}
#[test]
fn test_public_key_to_pem_pkcs1() {
let keypair = super::Rsa::generate(512).unwrap();
let pubkey_pem = keypair.public_key_to_pem_pkcs1().unwrap();
super::Rsa::public_key_from_pem_pkcs1(&pubkey_pem).unwrap();
}
#[test]
#[should_panic]
fn test_public_key_from_pem_pkcs1_generate_panic() {
let keypair = super::Rsa::generate(512).unwrap();
let pubkey_pem = keypair.public_key_to_pem().unwrap();
super::Rsa::public_key_from_pem_pkcs1(&pubkey_pem).unwrap();
}
#[test]
fn test_pem_pkcs1_encrypt() {
let keypair = super::Rsa::generate(2048).unwrap();
let pubkey_pem = keypair.public_key_to_pem_pkcs1().unwrap();
let pubkey = super::Rsa::public_key_from_pem_pkcs1(&pubkey_pem).unwrap();
let msg = b"Hello, world!";
let mut encrypted = vec![0; pubkey.size() as usize];
let len = pubkey
.public_encrypt(msg, &mut encrypted, Padding::PKCS1)
.unwrap();
assert!(len > msg.len());
let mut decrypted = vec![0; keypair.size() as usize];
let len = keypair
.private_decrypt(&encrypted, &mut decrypted, Padding::PKCS1)
.unwrap();
assert_eq!(len, msg.len());
assert_eq!(&decrypted[..len], msg);
}
#[test]
fn test_pem_pkcs1_padding() {
let keypair = super::Rsa::generate(2048).unwrap();
let pubkey_pem = keypair.public_key_to_pem_pkcs1().unwrap();
let pubkey = super::Rsa::public_key_from_pem_pkcs1(&pubkey_pem).unwrap();
let msg = b"foo";
let mut encrypted1 = vec![0; pubkey.size() as usize];
let mut encrypted2 = vec![0; pubkey.size() as usize];
let len1 = pubkey
.public_encrypt(msg, &mut encrypted1, Padding::PKCS1)
.unwrap();
let len2 = pubkey
.public_encrypt(msg, &mut encrypted2, Padding::PKCS1)
.unwrap();
assert!(len1 > (msg.len() + 1));
assert_eq!(len1, len2);
assert_ne!(encrypted1, encrypted2);
}
#[test]
#[allow(clippy::redundant_clone)]
fn clone() {
let key = Rsa::generate(2048).unwrap();
drop(key.clone());
}
#[test]
fn generate_with_e() {
let e = BigNum::from_u32(0x10001).unwrap();
Rsa::generate_with_e(2048, &e).unwrap();
}
}