#![allow(missing_docs)]
#[cfg(all(target_arch = "wasm32", target_os = "unknown"))]
use wasm_bindgen_test::{wasm_bindgen_test as test, wasm_bindgen_test_configure};
#[cfg(all(target_arch = "wasm32", target_os = "unknown"))]
wasm_bindgen_test_configure!(run_in_browser);
extern crate alloc;
use ring::{agreement, error, rand, test, test_file};
#[test]
fn agreement_traits() {
use alloc::vec::Vec;
let rng = rand::SystemRandom::new();
let private_key =
agreement::EphemeralPrivateKey::generate(&agreement::ECDH_P256, &rng).unwrap();
test::compile_time_assert_send::<agreement::EphemeralPrivateKey>();
test::compile_time_assert_sync::<agreement::EphemeralPrivateKey>();
assert_eq!(
format!("{:?}", &private_key),
"EphemeralPrivateKey { algorithm: Algorithm { curve: P256 } }"
);
let public_key = private_key.compute_public_key().unwrap();
test::compile_time_assert_clone::<agreement::PublicKey>();
test::compile_time_assert_send::<agreement::PublicKey>();
test::compile_time_assert_sync::<agreement::PublicKey>();
let _: &dyn core::fmt::Debug = &public_key;
test::compile_time_assert_clone::<agreement::UnparsedPublicKey<&[u8]>>();
test::compile_time_assert_copy::<agreement::UnparsedPublicKey<&[u8]>>();
test::compile_time_assert_sync::<agreement::UnparsedPublicKey<&[u8]>>();
test::compile_time_assert_clone::<agreement::UnparsedPublicKey<Vec<u8>>>();
test::compile_time_assert_sync::<agreement::UnparsedPublicKey<Vec<u8>>>();
let unparsed_public_key =
agreement::UnparsedPublicKey::new(&agreement::X25519, &[0x01, 0x02, 0x03]);
assert_eq!(
format!("{:?}", unparsed_public_key),
r#"UnparsedPublicKey { algorithm: Algorithm { curve: Curve25519 }, bytes: "010203" }"#
);
assert_eq!(unparsed_public_key.as_ref(), &[0x01, 0x02, 0x03]);
}
#[test]
fn agreement_agree_ephemeral() {
let rng = rand::SystemRandom::new();
test::run(test_file!("agreement_tests.txt"), |section, test_case| {
assert_eq!(section, "");
let curve_name = test_case.consume_string("Curve");
let alg = alg_from_curve_name(&curve_name);
let peer_public = agreement::UnparsedPublicKey::new(alg, test_case.consume_bytes("PeerQ"));
match test_case.consume_optional_string("Error") {
None => {
let my_private = test_case.consume_bytes("D");
let my_private = {
let rng = test::rand::FixedSliceRandom { bytes: &my_private };
agreement::EphemeralPrivateKey::generate(alg, &rng)?
};
let my_public = test_case.consume_bytes("MyQ");
let output = test_case.consume_bytes("Output");
assert_eq!(my_private.algorithm(), alg);
let computed_public = my_private.compute_public_key().unwrap();
assert_eq!(computed_public.as_ref(), &my_public[..]);
assert_eq!(my_private.algorithm(), alg);
let result = agreement::agree_ephemeral(my_private, &peer_public, |key_material| {
assert_eq!(key_material, &output[..]);
});
assert_eq!(result, Ok(()));
}
Some(_) => {
let dummy_private_key = agreement::EphemeralPrivateKey::generate(alg, &rng)?;
fn kdf_not_called(_: &[u8]) -> Result<(), ()> {
panic!(
"The KDF was called during ECDH when the peer's \
public key is invalid."
);
}
assert!(agreement::agree_ephemeral(
dummy_private_key,
&peer_public,
kdf_not_called
)
.is_err());
}
}
Ok(())
});
}
#[test]
fn test_agreement_ecdh_x25519_rfc_iterated() {
let mut k = h("0900000000000000000000000000000000000000000000000000000000000000");
let mut u = k.clone();
fn expect_iterated_x25519(
expected_result: &str,
range: core::ops::Range<usize>,
k: &mut Vec<u8>,
u: &mut Vec<u8>,
) {
for _ in range {
let new_k = x25519(k, u);
u.clone_from(k);
*k = new_k;
}
assert_eq!(&h(expected_result), k);
}
expect_iterated_x25519(
"422c8e7a6227d7bca1350b3e2bb7279f7897b87bb6854b783c60e80311ae3079",
0..1,
&mut k,
&mut u,
);
expect_iterated_x25519(
"684cf59ba83309552800ef566f2f4d3c1c3887c49360e3875f2eb94d99532c51",
1..1_000,
&mut k,
&mut u,
);
expect_iterated_x25519(
"2c125a20f639d504a7703d2e223c79a79de48c4ee8c23379aa19a62ecd211815",
1_000..10_000,
&mut k,
&mut u,
);
if cfg!(feature = "slow_tests") {
expect_iterated_x25519(
"7c3911e0ab2586fd864497297e575e6f3bc601c0883c30df5f4dd2d24f665424",
10_000..1_000_000,
&mut k,
&mut u,
);
}
}
fn x25519(private_key: &[u8], public_key: &[u8]) -> Vec<u8> {
x25519_(private_key, public_key).unwrap()
}
fn x25519_(private_key: &[u8], public_key: &[u8]) -> Result<Vec<u8>, error::Unspecified> {
let rng = test::rand::FixedSliceRandom { bytes: private_key };
let private_key = agreement::EphemeralPrivateKey::generate(&agreement::X25519, &rng)?;
let public_key = agreement::UnparsedPublicKey::new(&agreement::X25519, public_key);
agreement::agree_ephemeral(private_key, &public_key, |agreed_value| {
Vec::from(agreed_value)
})
}
fn h(s: &str) -> Vec<u8> {
match test::from_hex(s) {
Ok(v) => v,
Err(msg) => {
panic!("{} in {}", msg, s);
}
}
}
fn alg_from_curve_name(curve_name: &str) -> &'static agreement::Algorithm {
if curve_name == "P-256" {
&agreement::ECDH_P256
} else if curve_name == "P-384" {
&agreement::ECDH_P384
} else if curve_name == "X25519" {
&agreement::X25519
} else {
panic!("Unsupported curve: {}", curve_name);
}
}