vendor/p384-0.13.0/src/ecdsa.rs - toolchain/rustc - Git at Google

 //! Elliptic Curve Digital Signature Algorithm (ECDSA)
 //!
 //! This module contains support for computing and verifying ECDSA signatures.
 //! To use it, you will need to enable one of the two following Cargo features:
 //!
 //! - `ecdsa-core`: provides only the [`Signature`] type (which represents an
 //!   ECDSA/P-384 signature). Does not require the `arithmetic` feature. This is
 //!   useful for 3rd-party crates which wish to use the `Signature` type for
 //!   interoperability purposes (particularly in conjunction with the
 //!   [`signature::Signer`] trait. Example use cases for this include other
 //!   software implementations of ECDSA/P-384 and wrappers for cloud KMS
 //!   services or hardware devices (HSM or crypto hardware wallet).
 //! - `ecdsa`: provides `ecdsa-core` features plus the [`SigningKey`] and
 //!   [`VerifyingKey`] types which natively implement ECDSA/P-384 signing and
 //!   verification.
 //!
 //! ## Signing/Verification Example
 //!
 //! This example requires the `ecdsa` Cargo feature is enabled:
 //!
 //! ```
 //! # #[cfg(feature = "ecdsa")]
 //! # {
 //! use p384::ecdsa::{signature::Signer, Signature, SigningKey};
 //! use rand_core::OsRng; // requires 'getrandom' feature
 //!
 //! // Signing
 //! let signing_key = SigningKey::random(&mut OsRng); // Serialize with `::to_bytes()`
 //! let message = b"ECDSA proves knowledge of a secret number in the context of a single message";
 //! let signature: Signature = signing_key.sign(message);
 //!
 //! // Verification
 //! use p384::ecdsa::{signature::Verifier, VerifyingKey};
 //!
 //! let verifying_key = VerifyingKey::from(&signing_key); // Serialize with `::to_encoded_point()`
 //! assert!(verifying_key.verify(message, &signature).is_ok());
 //! # }
 //! ```

 pub use ecdsa_core::signature::{self, Error};
 #[cfg(feature = "ecdsa")]
 use {
     crate::{AffinePoint, Scalar},
     ecdsa_core::hazmat::{SignPrimitive, VerifyPrimitive},
 };

 use super::NistP384;

 /// ECDSA/P-384 signature (fixed-size)
 pub type Signature = ecdsa_core::Signature<NistP384>;

 /// ECDSA/P-384 signature (ASN.1 DER encoded)
 pub type DerSignature = ecdsa_core::der::Signature<NistP384>;

 /// ECDSA/P-384 signing key
 #[cfg(feature = "ecdsa")]
 pub type SigningKey = ecdsa_core::SigningKey<NistP384>;

 /// ECDSA/P-384 verification key (i.e. public key)
 #[cfg(feature = "ecdsa")]
 pub type VerifyingKey = ecdsa_core::VerifyingKey<NistP384>;

 #[cfg(feature = "sha384")]
 impl ecdsa_core::hazmat::DigestPrimitive for NistP384 {
     type Digest = sha2::Sha384;
 }

 #[cfg(feature = "ecdsa")]
 impl SignPrimitive<NistP384> for Scalar {}

 #[cfg(feature = "ecdsa")]
 impl VerifyPrimitive<NistP384> for AffinePoint {}

 #[cfg(all(test, feature = "ecdsa"))]
 mod tests {
     use crate::{
         ecdsa::{
             signature::hazmat::{PrehashSigner, PrehashVerifier},
             signature::Signer,
             Signature, SigningKey, VerifyingKey,
         },
         AffinePoint, EncodedPoint, SecretKey,
     };

     use elliptic_curve::{generic_array::GenericArray, sec1::FromEncodedPoint};
     use hex_literal::hex;
     use sha2::Digest;

     // Test vector from RFC 6979 Appendix 2.6 (NIST P-384 + SHA-384)
     // <https://tools.ietf.org/html/rfc6979#appendix-A.2.6>
     #[test]
     fn rfc6979() {
         let x = hex!("6b9d3dad2e1b8c1c05b19875b6659f4de23c3b667bf297ba9aa47740787137d896d5724e4c70a825f872c9ea60d2edf5");
         let signer = SigningKey::from_bytes(&x.into()).unwrap();
         let signature: Signature = signer.sign(b"sample");
         assert_eq!(
             signature.to_bytes().as_slice(),
             &hex!(
                 "94edbb92a5ecb8aad4736e56c691916b3f88140666ce9fa73d64c4ea95ad133c81a648152e44acf96e36dd1e80fabe46
                 99ef4aeb15f178cea1fe40db2603138f130e740a19624526203b6351d0a3a94fa329c145786e679e7b82c71a38628ac8"
             )
         );

         let signature: Signature = signer.sign(b"test");
         assert_eq!(
             signature.to_bytes().as_slice(),
             &hex!(
                 "8203b63d3c853e8d77227fb377bcf7b7b772e97892a80f36ab775d509d7a5feb0542a7f0812998da8f1dd3ca3cf023db
                 ddd0760448d42d8a43af45af836fce4de8be06b485e9b61b827c2f13173923e06a739f040649a667bf3b828246baa5a5"
             )
         );
     }

     // Test signing with PrehashSigner using SHA-256 which output is smaller than P-384 field size.
     #[test]
     fn prehash_signer_signing_with_sha256() {
         let x = hex!("6b9d3dad2e1b8c1c05b19875b6659f4de23c3b667bf297ba9aa47740787137d896d5724e4c70a825f872c9ea60d2edf5");
         let signer = SigningKey::from_bytes(&x.into()).unwrap();
         let digest = sha2::Sha256::digest(b"test");
         let signature: Signature = signer.sign_prehash(&digest).unwrap();
         assert_eq!(
             signature.to_bytes().as_slice(),
             &hex!(
                 "010c3ab1a300f8c9d63eafa9a41813f0c5416c08814bdfc0236458d6c2603d71c4941f4696e60aff5717476170bb6ab4
                 03c4ad6274c61691346b2178def879424726909af308596ffb6355a042f48a114e2eb28eaa6918592b4727961057c0c1"
             )
         );
     }

     // Test verifying with PrehashVerifier using SHA-256 which output is smaller than P-384 field size.
     #[test]
     fn prehash_signer_verification_with_sha256() {
         // The following test vector adapted from the FIPS 186-4 ECDSA test vectors
         // (P-384, SHA-256, from `SigGen.txt` in `186-4ecdsatestvectors.zip`)
         // <https://csrc.nist.gov/projects/cryptographic-algorithm-validation-program/digital-signatures>
         let verifier = VerifyingKey::from_affine(
             AffinePoint::from_encoded_point(
                 &EncodedPoint::from_affine_coordinates(
                     GenericArray::from_slice(&hex!("0400193b21f07cd059826e9453d3e96dd145041c97d49ff6b7047f86bb0b0439e909274cb9c282bfab88674c0765bc75")),
                     GenericArray::from_slice(&hex!("f70d89c52acbc70468d2c5ae75c76d7f69b76af62dcf95e99eba5dd11adf8f42ec9a425b0c5ec98e2f234a926b82a147")),
                     false,
                 ),
             ).unwrap()
         ).unwrap();
         let signature = Signature::from_scalars(
             GenericArray::clone_from_slice(&hex!("b11db00cdaf53286d4483f38cd02785948477ed7ebc2ad609054551da0ab0359978c61851788aa2ec3267946d440e878")),
             GenericArray::clone_from_slice(&hex!("16007873c5b0604ce68112a8fee973e8e2b6e3319c683a762ff5065a076512d7c98b27e74b7887671048ac027df8cbf2")),
         ).unwrap();
         let result = verifier.verify_prehash(
             &hex!("bbbd0a5f645d3fda10e288d172b299455f9dff00e0fbc2833e18cd017d7f3ed1"),
             &signature,
         );
         assert!(result.is_ok());
     }

     #[test]
     fn signing_secret_key_equivalent() {
         let raw_sk: [u8; 48] = [
             32, 52, 118, 9, 96, 116, 119, 172, 168, 251, 251, 197, 230, 33, 132, 85, 243, 25, 150,
             105, 121, 46, 248, 180, 102, 250, 168, 123, 220, 103, 121, 129, 68, 200, 72, 221, 3,
             102, 30, 237, 90, 198, 36, 97, 52, 12, 234, 150,
         ];

         let seck = SecretKey::from_bytes(&raw_sk.into()).unwrap();
         let sigk = SigningKey::from_bytes(&raw_sk.into()).unwrap();

         assert_eq!(seck.to_bytes().as_slice(), &raw_sk);
         assert_eq!(sigk.to_bytes().as_slice(), &raw_sk);
     }

     mod sign {
         use crate::{test_vectors::ecdsa::ECDSA_TEST_VECTORS, NistP384};
         ecdsa_core::new_signing_test!(NistP384, ECDSA_TEST_VECTORS);
     }

     mod verify {
         use crate::{test_vectors::ecdsa::ECDSA_TEST_VECTORS, NistP384};
         ecdsa_core::new_verification_test!(NistP384, ECDSA_TEST_VECTORS);
     }

     mod wycheproof {
         use crate::NistP384;
         ecdsa_core::new_wycheproof_test!(wycheproof, "wycheproof", NistP384);
     }
 }
	//! Elliptic Curve Digital Signature Algorithm (ECDSA)
	//!
	//! This module contains support for computing and verifying ECDSA signatures.
	//! To use it, you will need to enable one of the two following Cargo features:
	//!
	//! - `ecdsa-core`: provides only the [`Signature`] type (which represents an
	//! ECDSA/P-384 signature). Does not require the `arithmetic` feature. This is
	//! useful for 3rd-party crates which wish to use the `Signature` type for
	//! interoperability purposes (particularly in conjunction with the
	//! [`signature::Signer`] trait. Example use cases for this include other
	//! software implementations of ECDSA/P-384 and wrappers for cloud KMS
	//! services or hardware devices (HSM or crypto hardware wallet).
	//! - `ecdsa`: provides `ecdsa-core` features plus the [`SigningKey`] and
	//! [`VerifyingKey`] types which natively implement ECDSA/P-384 signing and
	//! verification.
	//!
	//! ## Signing/Verification Example
	//!
	//! This example requires the `ecdsa` Cargo feature is enabled:
	//!
	//! ```
	//! # #[cfg(feature = "ecdsa")]
	//! # {
	//! use p384::ecdsa::{signature::Signer, Signature, SigningKey};
	//! use rand_core::OsRng; // requires 'getrandom' feature
	//!
	//! // Signing
	//! let signing_key = SigningKey::random(&mut OsRng); // Serialize with `::to_bytes()`
	//! let message = b"ECDSA proves knowledge of a secret number in the context of a single message";
	//! let signature: Signature = signing_key.sign(message);
	//!
	//! // Verification
	//! use p384::ecdsa::{signature::Verifier, VerifyingKey};
	//!
	//! let verifying_key = VerifyingKey::from(&signing_key); // Serialize with `::to_encoded_point()`
	//! assert!(verifying_key.verify(message, &signature).is_ok());
	//! # }
	//! ```

	pub use ecdsa_core::signature::{self, Error};
	#[cfg(feature = "ecdsa")]
	use {
	crate::{AffinePoint, Scalar},
	ecdsa_core::hazmat::{SignPrimitive, VerifyPrimitive},
	};

	use super::NistP384;

	/// ECDSA/P-384 signature (fixed-size)
	pub type Signature = ecdsa_core::Signature<NistP384>;

	/// ECDSA/P-384 signature (ASN.1 DER encoded)
	pub type DerSignature = ecdsa_core::der::Signature<NistP384>;

	/// ECDSA/P-384 signing key
	#[cfg(feature = "ecdsa")]
	pub type SigningKey = ecdsa_core::SigningKey<NistP384>;

	/// ECDSA/P-384 verification key (i.e. public key)
	#[cfg(feature = "ecdsa")]
	pub type VerifyingKey = ecdsa_core::VerifyingKey<NistP384>;

	#[cfg(feature = "sha384")]
	impl ecdsa_core::hazmat::DigestPrimitive for NistP384 {
	type Digest = sha2::Sha384;
	}

	#[cfg(feature = "ecdsa")]
	impl SignPrimitive<NistP384> for Scalar {}

	#[cfg(feature = "ecdsa")]
	impl VerifyPrimitive<NistP384> for AffinePoint {}

	#[cfg(all(test, feature = "ecdsa"))]
	mod tests {
	use crate::{
	ecdsa::{
	signature::hazmat::{PrehashSigner, PrehashVerifier},
	signature::Signer,
	Signature, SigningKey, VerifyingKey,
	},
	AffinePoint, EncodedPoint, SecretKey,
	};

	use elliptic_curve::{generic_array::GenericArray, sec1::FromEncodedPoint};
	use hex_literal::hex;
	use sha2::Digest;

	// Test vector from RFC 6979 Appendix 2.6 (NIST P-384 + SHA-384)
	// <https://tools.ietf.org/html/rfc6979#appendix-A.2.6>
	#[test]
	fn rfc6979() {
	let x = hex!("6b9d3dad2e1b8c1c05b19875b6659f4de23c3b667bf297ba9aa47740787137d896d5724e4c70a825f872c9ea60d2edf5");
	let signer = SigningKey::from_bytes(&x.into()).unwrap();
	let signature: Signature = signer.sign(b"sample");
	assert_eq!(
	signature.to_bytes().as_slice(),
	&hex!(
	"94edbb92a5ecb8aad4736e56c691916b3f88140666ce9fa73d64c4ea95ad133c81a648152e44acf96e36dd1e80fabe46
	99ef4aeb15f178cea1fe40db2603138f130e740a19624526203b6351d0a3a94fa329c145786e679e7b82c71a38628ac8"
	)
	);

	let signature: Signature = signer.sign(b"test");
	assert_eq!(
	signature.to_bytes().as_slice(),
	&hex!(
	"8203b63d3c853e8d77227fb377bcf7b7b772e97892a80f36ab775d509d7a5feb0542a7f0812998da8f1dd3ca3cf023db
	ddd0760448d42d8a43af45af836fce4de8be06b485e9b61b827c2f13173923e06a739f040649a667bf3b828246baa5a5"
	)
	);
	}

	// Test signing with PrehashSigner using SHA-256 which output is smaller than P-384 field size.
	#[test]
	fn prehash_signer_signing_with_sha256() {
	let x = hex!("6b9d3dad2e1b8c1c05b19875b6659f4de23c3b667bf297ba9aa47740787137d896d5724e4c70a825f872c9ea60d2edf5");
	let signer = SigningKey::from_bytes(&x.into()).unwrap();
	let digest = sha2::Sha256::digest(b"test");
	let signature: Signature = signer.sign_prehash(&digest).unwrap();
	assert_eq!(
	signature.to_bytes().as_slice(),
	&hex!(
	"010c3ab1a300f8c9d63eafa9a41813f0c5416c08814bdfc0236458d6c2603d71c4941f4696e60aff5717476170bb6ab4
	03c4ad6274c61691346b2178def879424726909af308596ffb6355a042f48a114e2eb28eaa6918592b4727961057c0c1"
	)
	);
	}

	// Test verifying with PrehashVerifier using SHA-256 which output is smaller than P-384 field size.
	#[test]
	fn prehash_signer_verification_with_sha256() {
	// The following test vector adapted from the FIPS 186-4 ECDSA test vectors
	// (P-384, SHA-256, from `SigGen.txt` in `186-4ecdsatestvectors.zip`)
	// <https://csrc.nist.gov/projects/cryptographic-algorithm-validation-program/digital-signatures>
	let verifier = VerifyingKey::from_affine(
	AffinePoint::from_encoded_point(
	&EncodedPoint::from_affine_coordinates(
	GenericArray::from_slice(&hex!("0400193b21f07cd059826e9453d3e96dd145041c97d49ff6b7047f86bb0b0439e909274cb9c282bfab88674c0765bc75")),
	GenericArray::from_slice(&hex!("f70d89c52acbc70468d2c5ae75c76d7f69b76af62dcf95e99eba5dd11adf8f42ec9a425b0c5ec98e2f234a926b82a147")),
	false,
	),
	).unwrap()
	).unwrap();
	let signature = Signature::from_scalars(
	GenericArray::clone_from_slice(&hex!("b11db00cdaf53286d4483f38cd02785948477ed7ebc2ad609054551da0ab0359978c61851788aa2ec3267946d440e878")),
	GenericArray::clone_from_slice(&hex!("16007873c5b0604ce68112a8fee973e8e2b6e3319c683a762ff5065a076512d7c98b27e74b7887671048ac027df8cbf2")),
	).unwrap();
	let result = verifier.verify_prehash(
	&hex!("bbbd0a5f645d3fda10e288d172b299455f9dff00e0fbc2833e18cd017d7f3ed1"),
	&signature,
	);
	assert!(result.is_ok());
	}

	#[test]
	fn signing_secret_key_equivalent() {
	let raw_sk: [u8; 48] = [
	32, 52, 118, 9, 96, 116, 119, 172, 168, 251, 251, 197, 230, 33, 132, 85, 243, 25, 150,
	105, 121, 46, 248, 180, 102, 250, 168, 123, 220, 103, 121, 129, 68, 200, 72, 221, 3,
	102, 30, 237, 90, 198, 36, 97, 52, 12, 234, 150,
	];

	let seck = SecretKey::from_bytes(&raw_sk.into()).unwrap();
	let sigk = SigningKey::from_bytes(&raw_sk.into()).unwrap();

	assert_eq!(seck.to_bytes().as_slice(), &raw_sk);
	assert_eq!(sigk.to_bytes().as_slice(), &raw_sk);
	}

	mod sign {
	use crate::{test_vectors::ecdsa::ECDSA_TEST_VECTORS, NistP384};
	ecdsa_core::new_signing_test!(NistP384, ECDSA_TEST_VECTORS);
	}

	mod verify {
	use crate::{test_vectors::ecdsa::ECDSA_TEST_VECTORS, NistP384};
	ecdsa_core::new_verification_test!(NistP384, ECDSA_TEST_VECTORS);
	}

	mod wycheproof {
	use crate::NistP384;
	ecdsa_core::new_wycheproof_test!(wycheproof, "wycheproof", NistP384);
	}
	}