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// -*- mode: rust; -*- // // This file is part of ed25519-dalek. // Copyright (c) 2017-2019 isis lovecruft // See LICENSE for licensing information. // // Authors: // - isis agora lovecruft <[email protected]> //! A Rust implementation of ed25519 key generation, signing, and verification. //! //! # Example //! //! Creating an ed25519 signature on a message is simple. //! //! First, we need to generate a `Keypair`, which includes both public and //! secret halves of an asymmetric key. To do so, we need a cryptographically //! secure pseudorandom number generator (CSPRNG). For this example, we'll use //! the operating system's builtin PRNG: //! //! ``` //! extern crate rand; //! extern crate ed25519_dalek; //! //! # #[cfg(feature = "std")] //! # fn main() { //! use rand::rngs::OsRng; //! use ed25519_dalek::Keypair; //! use ed25519_dalek::Signature; //! //! let mut csprng = OsRng{}; //! let keypair: Keypair = Keypair::generate(&mut csprng); //! # } //! # //! # #[cfg(not(feature = "std"))] //! # fn main() { } //! ``` //! //! We can now use this `keypair` to sign a message: //! //! ``` //! # extern crate rand; //! # extern crate ed25519_dalek; //! # fn main() { //! # use rand::rngs::OsRng; //! # use ed25519_dalek::Keypair; //! # let mut csprng = OsRng{}; //! # let keypair: Keypair = Keypair::generate(&mut csprng); //! use ed25519_dalek::{Signature, Signer}; //! let message: &[u8] = b"This is a test of the tsunami alert system."; //! let signature: Signature = keypair.sign(message); //! # } //! ``` //! //! As well as to verify that this is, indeed, a valid signature on //! that `message`: //! //! ``` //! # extern crate rand; //! # extern crate ed25519_dalek; //! # fn main() { //! # use rand::rngs::OsRng; //! # use ed25519_dalek::{Keypair, Signature, Signer}; //! # let mut csprng = OsRng{}; //! # let keypair: Keypair = Keypair::generate(&mut csprng); //! # let message: &[u8] = b"This is a test of the tsunami alert system."; //! # let signature: Signature = keypair.sign(message); //! use ed25519_dalek::Verifier; //! assert!(keypair.verify(message, &signature).is_ok()); //! # } //! ``` //! //! Anyone else, given the `public` half of the `keypair` can also easily //! verify this signature: //! //! ``` //! # extern crate rand; //! # extern crate ed25519_dalek; //! # fn main() { //! # use rand::rngs::OsRng; //! # use ed25519_dalek::Keypair; //! # use ed25519_dalek::Signature; //! # use ed25519_dalek::Signer; //! use ed25519_dalek::{PublicKey, Verifier}; //! # let mut csprng = OsRng{}; //! # let keypair: Keypair = Keypair::generate(&mut csprng); //! # let message: &[u8] = b"This is a test of the tsunami alert system."; //! # let signature: Signature = keypair.sign(message); //! //! let public_key: PublicKey = keypair.public; //! assert!(public_key.verify(message, &signature).is_ok()); //! # } //! ``` //! //! ## Serialisation //! //! `PublicKey`s, `SecretKey`s, `Keypair`s, and `Signature`s can be serialised //! into byte-arrays by calling `.to_bytes()`. It's perfectly acceptible and //! safe to transfer and/or store those bytes. (Of course, never transfer your //! secret key to anyone else, since they will only need the public key to //! verify your signatures!) //! //! ``` //! # extern crate rand; //! # extern crate ed25519_dalek; //! # fn main() { //! # use rand::rngs::OsRng; //! # use ed25519_dalek::{Keypair, Signature, Signer, PublicKey}; //! use ed25519_dalek::{PUBLIC_KEY_LENGTH, SECRET_KEY_LENGTH, KEYPAIR_LENGTH, SIGNATURE_LENGTH}; //! # let mut csprng = OsRng{}; //! # let keypair: Keypair = Keypair::generate(&mut csprng); //! # let message: &[u8] = b"This is a test of the tsunami alert system."; //! # let signature: Signature = keypair.sign(message); //! # let public_key: PublicKey = keypair.public; //! //! let public_key_bytes: [u8; PUBLIC_KEY_LENGTH] = public_key.to_bytes(); //! let secret_key_bytes: [u8; SECRET_KEY_LENGTH] = keypair.secret.to_bytes(); //! let keypair_bytes: [u8; KEYPAIR_LENGTH] = keypair.to_bytes(); //! let signature_bytes: [u8; SIGNATURE_LENGTH] = signature.to_bytes(); //! # } //! ``` //! //! And similarly, decoded from bytes with `::from_bytes()`: //! //! ``` //! # extern crate rand; //! # extern crate ed25519_dalek; //! # use std::convert::TryFrom; //! # use rand::rngs::OsRng; //! # use ed25519_dalek::{Keypair, Signature, Signer, PublicKey, SecretKey, SignatureError}; //! # use ed25519_dalek::{PUBLIC_KEY_LENGTH, SECRET_KEY_LENGTH, KEYPAIR_LENGTH, SIGNATURE_LENGTH}; //! # fn do_test() -> Result<(SecretKey, PublicKey, Keypair, Signature), SignatureError> { //! # let mut csprng = OsRng{}; //! # let keypair_orig: Keypair = Keypair::generate(&mut csprng); //! # let message: &[u8] = b"This is a test of the tsunami alert system."; //! # let signature_orig: Signature = keypair_orig.sign(message); //! # let public_key_bytes: [u8; PUBLIC_KEY_LENGTH] = keypair_orig.public.to_bytes(); //! # let secret_key_bytes: [u8; SECRET_KEY_LENGTH] = keypair_orig.secret.to_bytes(); //! # let keypair_bytes: [u8; KEYPAIR_LENGTH] = keypair_orig.to_bytes(); //! # let signature_bytes: [u8; SIGNATURE_LENGTH] = signature_orig.to_bytes(); //! # //! let public_key: PublicKey = PublicKey::from_bytes(&public_key_bytes)?; //! let secret_key: SecretKey = SecretKey::from_bytes(&secret_key_bytes)?; //! let keypair: Keypair = Keypair::from_bytes(&keypair_bytes)?; //! let signature: Signature = Signature::try_from(&signature_bytes[..])?; //! # //! # Ok((secret_key, public_key, keypair, signature)) //! # } //! # fn main() { //! # do_test(); //! # } //! ``` //! //! ### Using Serde //! //! If you prefer the bytes to be wrapped in another serialisation format, all //! types additionally come with built-in [serde](https://serde.rs) support by //! building `ed25519-dalek` via: //! //! ```bash //! $ cargo build --features="serde" //! ``` //! //! They can be then serialised into any of the wire formats which serde supports. //! For example, using [bincode](https://github.com/TyOverby/bincode): //! //! ``` //! # extern crate rand; //! # extern crate ed25519_dalek; //! # #[cfg(feature = "serde")] //! # extern crate serde_crate as serde; //! # #[cfg(feature = "serde")] //! # extern crate bincode; //! //! # #[cfg(feature = "serde")] //! # fn main() { //! # use rand::rngs::OsRng; //! # use ed25519_dalek::{Keypair, Signature, Signer, Verifier, PublicKey}; //! use bincode::serialize; //! # let mut csprng = OsRng{}; //! # let keypair: Keypair = Keypair::generate(&mut csprng); //! # let message: &[u8] = b"This is a test of the tsunami alert system."; //! # let signature: Signature = keypair.sign(message); //! # let public_key: PublicKey = keypair.public; //! # let verified: bool = public_key.verify(message, &signature).is_ok(); //! //! let encoded_public_key: Vec<u8> = serialize(&public_key).unwrap(); //! let encoded_signature: Vec<u8> = serialize(&signature).unwrap(); //! # } //! # #[cfg(not(feature = "serde"))] //! # fn main() {} //! ``` //! //! After sending the `encoded_public_key` and `encoded_signature`, the //! recipient may deserialise them and verify: //! //! ``` //! # extern crate rand; //! # extern crate ed25519_dalek; //! # #[cfg(feature = "serde")] //! # extern crate serde_crate as serde; //! # #[cfg(feature = "serde")] //! # extern crate bincode; //! # //! # #[cfg(feature = "serde")] //! # fn main() { //! # use rand::rngs::OsRng; //! # use ed25519_dalek::{Keypair, Signature, Signer, Verifier, PublicKey}; //! # use bincode::serialize; //! use bincode::deserialize; //! //! # let mut csprng = OsRng{}; //! # let keypair: Keypair = Keypair::generate(&mut csprng); //! let message: &[u8] = b"This is a test of the tsunami alert system."; //! # let signature: Signature = keypair.sign(message); //! # let public_key: PublicKey = keypair.public; //! # let verified: bool = public_key.verify(message, &signature).is_ok(); //! # let encoded_public_key: Vec<u8> = serialize(&public_key).unwrap(); //! # let encoded_signature: Vec<u8> = serialize(&signature).unwrap(); //! let decoded_public_key: PublicKey = deserialize(&encoded_public_key).unwrap(); //! let decoded_signature: Signature = deserialize(&encoded_signature).unwrap(); //! //! # assert_eq!(public_key, decoded_public_key); //! # assert_eq!(signature, decoded_signature); //! # //! let verified: bool = decoded_public_key.verify(&message, &decoded_signature).is_ok(); //! //! assert!(verified); //! # } //! # #[cfg(not(feature = "serde"))] //! # fn main() {} //! ``` #![no_std] #![warn(future_incompatible)] #![deny(missing_docs)] // refuse to compile if documentation is missing #![cfg(not(test))] #![forbid(unsafe_code)] #[cfg(any(feature = "std", test))] #[macro_use] extern crate std; pub extern crate ed25519; #[cfg(all(feature = "alloc", not(feature = "std")))] extern crate alloc; extern crate curve25519_dalek; #[cfg(all(any(feature = "batch", feature = "batch_deterministic"), any(feature = "std", feature = "alloc")))] extern crate merlin; #[cfg(any(feature = "batch", feature = "std", feature = "alloc", test))] extern crate rand; #[cfg(feature = "serde")] extern crate serde_crate as serde; extern crate sha2; extern crate zeroize; #[cfg(all(any(feature = "batch", feature = "batch_deterministic"), any(feature = "std", feature = "alloc")))] mod batch; mod constants; mod keypair; mod errors; mod public; mod secret; mod signature; pub use curve25519_dalek::digest::Digest; #[cfg(all(any(feature = "batch", feature = "batch_deterministic"), any(feature = "std", feature = "alloc")))] pub use crate::batch::*; pub use crate::constants::*; pub use crate::errors::*; pub use crate::keypair::*; pub use crate::public::*; pub use crate::secret::*; // Re-export the `Signer` and `Verifier` traits from the `signature` crate pub use ed25519::signature::{Signer, Verifier}; pub use ed25519::Signature;