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// Copyright 2015-2017 Brian Smith. // // Permission to use, copy, modify, and/or distribute this software for any // purpose with or without fee is hereby granted, provided that the above // copyright notice and this permission notice appear in all copies. // // THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHORS DISCLAIM ALL WARRANTIES // WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY // SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES // WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION // OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN // CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. //! Key Agreement: ECDH, including X25519. //! //! # Example //! //! Note that this example uses X25519, but ECDH using NIST P-256/P-384 is done //! exactly the same way, just substituting //! `agreement::ECDH_P256`/`agreement::ECDH_P384` for `agreement::X25519`. //! //! ``` //! use ring::{agreement, rand}; //! //! let rng = rand::SystemRandom::new(); //! //! let my_private_key = agreement::EphemeralPrivateKey::generate(&agreement::X25519, &rng)?; //! //! // Make `my_public_key` a byte slice containing my public key. In a real //! // application, this would be sent to the peer in an encoded protocol //! // message. //! let my_public_key = my_private_key.compute_public_key()?; //! //! let peer_public_key = { //! // In a real application, the peer public key would be parsed out of a //! // protocol message. Here we just generate one. //! let peer_public_key = { //! let peer_private_key = //! agreement::EphemeralPrivateKey::generate(&agreement::X25519, &rng)?; //! peer_private_key.compute_public_key()? //! }; //! //! agreement::UnparsedPublicKey::new(&agreement::X25519, peer_public_key) //! }; //! //! agreement::agree_ephemeral( //! my_private_key, //! &peer_public_key, //! ring::error::Unspecified, //! |_key_material| { //! // In a real application, we'd apply a KDF to the key material and the //! // public keys (as recommended in RFC 7748) and then derive session //! // keys from the result. We omit all that here. //! Ok(()) //! }, //! )?; //! //! # Ok::<(), ring::error::Unspecified>(()) //! ``` // The "NSA Guide" steps here are from from section 3.1, "Ephemeral Unified // Model." use crate::{cpu, debug, ec, error, rand}; use untrusted; pub use crate::ec::{ curve25519::x25519::X25519, suite_b::ecdh::{ECDH_P256, ECDH_P384}, }; /// A key agreement algorithm. pub struct Algorithm { pub(crate) curve: &'static ec::Curve, pub(crate) ecdh: fn( out: &mut [u8], private_key: &ec::Seed, peer_public_key: untrusted::Input, ) -> Result<(), error::Unspecified>, } derive_debug_via_field!(Algorithm, curve); impl Eq for Algorithm {} impl PartialEq for Algorithm { fn eq(&self, other: &Algorithm) -> bool { self.curve.id == other.curve.id } } /// An ephemeral private key for use (only) with `agree_ephemeral`. The /// signature of `agree_ephemeral` ensures that an `EphemeralPrivateKey` can be /// used for at most one key agreement. pub struct EphemeralPrivateKey { private_key: ec::Seed, algorithm: &'static Algorithm, } derive_debug_via_field!( EphemeralPrivateKey, stringify!(EphemeralPrivateKey), algorithm ); impl EphemeralPrivateKey { /// Generate a new ephemeral private key for the given algorithm. pub fn generate( alg: &'static Algorithm, rng: &dyn rand::SecureRandom, ) -> Result<Self, error::Unspecified> { let cpu_features = cpu::features(); // NSA Guide Step 1. // // This only handles the key generation part of step 1. The rest of // step one is done by `compute_public_key()`. let private_key = ec::Seed::generate(&alg.curve, rng, cpu_features)?; Ok(Self { private_key, algorithm: alg, }) } /// Computes the public key from the private key. #[inline(always)] pub fn compute_public_key(&self) -> Result<PublicKey, error::Unspecified> { // NSA Guide Step 1. // // Obviously, this only handles the part of Step 1 between the private // key generation and the sending of the public key to the peer. `out` // is what should be sent to the peer. self.private_key .compute_public_key() .map(|public_key| PublicKey { algorithm: self.algorithm, bytes: public_key, }) } /// The algorithm for the private key. #[inline] pub fn algorithm(&self) -> &'static Algorithm { self.algorithm } #[cfg(test)] pub fn bytes(&self) -> &[u8] { self.private_key.bytes_less_safe() } } /// A public key for key agreement. #[derive(Clone)] pub struct PublicKey { algorithm: &'static Algorithm, bytes: ec::PublicKey, } impl AsRef<[u8]> for PublicKey { fn as_ref(&self) -> &[u8] { self.bytes.as_ref() } } impl core::fmt::Debug for PublicKey { fn fmt(&self, f: &mut core::fmt::Formatter) -> Result<(), core::fmt::Error> { f.debug_struct("PublicKey") .field("algorithm", &self.algorithm) .field("bytes", &debug::HexStr(self.as_ref())) .finish() } } impl PublicKey { /// The algorithm for the public key. #[inline] pub fn algorithm(&self) -> &'static Algorithm { self.algorithm } } /// An unparsed, possibly malformed, public key for key agreement. pub struct UnparsedPublicKey<B: AsRef<[u8]>> { algorithm: &'static Algorithm, bytes: B, } impl<B: Copy> Copy for UnparsedPublicKey<B> where B: AsRef<[u8]> {} impl<B: Clone> Clone for UnparsedPublicKey<B> where B: AsRef<[u8]>, { fn clone(&self) -> Self { Self { algorithm: self.algorithm, bytes: self.bytes.clone(), } } } impl<B: core::fmt::Debug> core::fmt::Debug for UnparsedPublicKey<B> where B: AsRef<[u8]>, { fn fmt(&self, f: &mut core::fmt::Formatter) -> Result<(), core::fmt::Error> { f.debug_struct("UnparsedPublicKey") .field("algorithm", &self.algorithm) .field("bytes", &debug::HexStr(self.bytes.as_ref())) .finish() } } impl<B: AsRef<[u8]>> UnparsedPublicKey<B> { /// Constructs a new `UnparsedPublicKey`. pub fn new(algorithm: &'static Algorithm, bytes: B) -> Self { Self { algorithm, bytes } } /// TODO: doc #[inline] pub fn algorithm(&self) -> &'static Algorithm { self.algorithm } /// TODO: doc #[inline] pub fn bytes(&self) -> &B { &self.bytes } } /// Performs a key agreement with an ephemeral private key and the given public /// key. /// /// `my_private_key` is the ephemeral private key to use. Since it is moved, it /// will not be usable after calling `agree_ephemeral`, thus guaranteeing that /// the key is used for only one key agreement. /// /// `peer_public_key` is the peer's public key. `agree_ephemeral` will return /// `Err(error_value)` if it does not match `my_private_key's` algorithm/curve. /// `agree_ephemeral` verifies that it is encoded in the standard form for the /// algorithm and that the key is *valid*; see the algorithm's documentation for /// details on how keys are to be encoded and what constitutes a valid key for /// that algorithm. /// /// `error_value` is the value to return if an error occurs before `kdf` is /// called, e.g. when decoding of the peer's public key fails or when the public /// key is otherwise invalid. /// /// After the key agreement is done, `agree_ephemeral` calls `kdf` with the raw /// key material from the key agreement operation and then returns what `kdf` /// returns. #[inline] pub fn agree_ephemeral<B: AsRef<[u8]>, F, R, E>( my_private_key: EphemeralPrivateKey, peer_public_key: &UnparsedPublicKey<B>, error_value: E, kdf: F, ) -> Result<R, E> where F: FnOnce(&[u8]) -> Result<R, E>, { let peer_public_key = UnparsedPublicKey { algorithm: peer_public_key.algorithm, bytes: peer_public_key.bytes.as_ref(), }; agree_ephemeral_(my_private_key, peer_public_key, error_value, kdf) } fn agree_ephemeral_<F, R, E>( my_private_key: EphemeralPrivateKey, peer_public_key: UnparsedPublicKey<&[u8]>, error_value: E, kdf: F, ) -> Result<R, E> where F: FnOnce(&[u8]) -> Result<R, E>, { // NSA Guide Prerequisite 1. // // The domain parameters are hard-coded. This check verifies that the // peer's public key's domain parameters match the domain parameters of // this private key. if peer_public_key.algorithm != my_private_key.algorithm { return Err(error_value); } let alg = &my_private_key.algorithm; // NSA Guide Prerequisite 2, regarding which KDFs are allowed, is delegated // to the caller. // NSA Guide Prerequisite 3, "Prior to or during the key-agreement process, // each party shall obtain the identifier associated with the other party // during the key-agreement scheme," is delegated to the caller. // NSA Guide Step 1 is handled by `EphemeralPrivateKey::generate()` and // `EphemeralPrivateKey::compute_public_key()`. let mut shared_key = [0u8; ec::ELEM_MAX_BYTES]; let shared_key = &mut shared_key[..alg.curve.elem_scalar_seed_len]; // NSA Guide Steps 2, 3, and 4. // // We have a pretty liberal interpretation of the NIST's spec's "Destroy" // that doesn't meet the NSA requirement to "zeroize." (alg.ecdh)( shared_key, &my_private_key.private_key, untrusted::Input::from(peer_public_key.bytes), ) .map_err(|_| error_value)?; // NSA Guide Steps 5 and 6. // // Again, we have a pretty liberal interpretation of the NIST's spec's // "Destroy" that doesn't meet the NSA requirement to "zeroize." kdf(shared_key) }