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// This file is part of Substrate. // Copyright (C) 2020-2021 Parity Technologies (UK) Ltd. // SPDX-License-Identifier: Apache-2.0 // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. //! Keystore traits pub mod testing; pub mod vrf; use std::sync::Arc; use async_trait::async_trait; use futures::{executor::block_on, future::join_all}; use sp_core::{ crypto::{KeyTypeId, CryptoTypePublicPair}, ed25519, sr25519, ecdsa, }; use crate::vrf::{VRFTranscriptData, VRFSignature}; /// CryptoStore error #[derive(Debug, derive_more::Display)] pub enum Error { /// Public key type is not supported #[display(fmt="Key not supported: {:?}", _0)] KeyNotSupported(KeyTypeId), /// Pair not found for public key and KeyTypeId #[display(fmt="Pair was not found: {}", _0)] PairNotFound(String), /// Validation error #[display(fmt="Validation error: {}", _0)] ValidationError(String), /// Keystore unavailable #[display(fmt="Keystore unavailable")] Unavailable, /// Programming errors #[display(fmt="An unknown keystore error occurred: {}", _0)] Other(String) } /// Something that generates, stores and provides access to keys. #[async_trait] pub trait CryptoStore: Send + Sync { /// Returns all sr25519 public keys for the given key type. async fn sr25519_public_keys(&self, id: KeyTypeId) -> Vec<sr25519::Public>; /// Generate a new sr25519 key pair for the given key type and an optional seed. /// /// If the given seed is `Some(_)`, the key pair will only be stored in memory. /// /// Returns the public key of the generated key pair. async fn sr25519_generate_new( &self, id: KeyTypeId, seed: Option<&str>, ) -> Result<sr25519::Public, Error>; /// Returns all ed25519 public keys for the given key type. async fn ed25519_public_keys(&self, id: KeyTypeId) -> Vec<ed25519::Public>; /// Generate a new ed25519 key pair for the given key type and an optional seed. /// /// If the given seed is `Some(_)`, the key pair will only be stored in memory. /// /// Returns the public key of the generated key pair. async fn ed25519_generate_new( &self, id: KeyTypeId, seed: Option<&str>, ) -> Result<ed25519::Public, Error>; /// Returns all ecdsa public keys for the given key type. async fn ecdsa_public_keys(&self, id: KeyTypeId) -> Vec<ecdsa::Public>; /// Generate a new ecdsa key pair for the given key type and an optional seed. /// /// If the given seed is `Some(_)`, the key pair will only be stored in memory. /// /// Returns the public key of the generated key pair. async fn ecdsa_generate_new( &self, id: KeyTypeId, seed: Option<&str>, ) -> Result<ecdsa::Public, Error>; /// Insert a new key. This doesn't require any known of the crypto; but a public key must be /// manually provided. /// /// Places it into the file system store. /// /// `Err` if there's some sort of weird filesystem error, but should generally be `Ok`. async fn insert_unknown( &self, id: KeyTypeId, suri: &str, public: &[u8] ) -> Result<(), ()>; /// Find intersection between provided keys and supported keys /// /// Provided a list of (CryptoTypeId,[u8]) pairs, this would return /// a filtered set of public keys which are supported by the keystore. async fn supported_keys( &self, id: KeyTypeId, keys: Vec<CryptoTypePublicPair> ) -> Result<Vec<CryptoTypePublicPair>, Error>; /// List all supported keys /// /// Returns a set of public keys the signer supports. async fn keys(&self, id: KeyTypeId) -> Result<Vec<CryptoTypePublicPair>, Error>; /// Checks if the private keys for the given public key and key type combinations exist. /// /// Returns `true` iff all private keys could be found. async fn has_keys(&self, public_keys: &[(Vec<u8>, KeyTypeId)]) -> bool; /// Sign with key /// /// Signs a message with the private key that matches /// the public key passed. /// /// Returns the SCALE encoded signature if key is found & supported, /// an error otherwise. async fn sign_with( &self, id: KeyTypeId, key: &CryptoTypePublicPair, msg: &[u8], ) -> Result<Vec<u8>, Error>; /// Sign with any key /// /// Given a list of public keys, find the first supported key and /// sign the provided message with that key. /// /// Returns a tuple of the used key and the SCALE encoded signature. async fn sign_with_any( &self, id: KeyTypeId, keys: Vec<CryptoTypePublicPair>, msg: &[u8] ) -> Result<(CryptoTypePublicPair, Vec<u8>), Error> { if keys.len() == 1 { return self.sign_with(id, &keys[0], msg).await.map(|s| (keys[0].clone(), s)); } else { for k in self.supported_keys(id, keys).await? { if let Ok(sign) = self.sign_with(id, &k, msg).await { return Ok((k, sign)); } } } Err(Error::KeyNotSupported(id)) } /// Sign with all keys /// /// Provided a list of public keys, sign a message with /// each key given that the key is supported. /// /// Returns a list of `Result`s each representing the SCALE encoded /// signature of each key or a Error for non-supported keys. async fn sign_with_all( &self, id: KeyTypeId, keys: Vec<CryptoTypePublicPair>, msg: &[u8], ) -> Result<Vec<Result<Vec<u8>, Error>>, ()> { let futs = keys.iter() .map(|k| self.sign_with(id, k, msg)); Ok(join_all(futs).await) } /// Generate VRF signature for given transcript data. /// /// Receives KeyTypeId and Public key to be able to map /// them to a private key that exists in the keystore which /// is, in turn, used for signing the provided transcript. /// /// Returns a result containing the signature data. /// Namely, VRFOutput and VRFProof which are returned /// inside the `VRFSignature` container struct. /// /// This function will return an error in the cases where /// the public key and key type provided do not match a private /// key in the keystore. Or, in the context of remote signing /// an error could be a network one. async fn sr25519_vrf_sign( &self, key_type: KeyTypeId, public: &sr25519::Public, transcript_data: VRFTranscriptData, ) -> Result<VRFSignature, Error>; } /// Sync version of the CryptoStore /// /// Some parts of Substrate still rely on a sync version of the `CryptoStore`. /// To make the transition easier this auto trait wraps any async `CryptoStore` and /// exposes a `sync` interface using `block_on`. Usage of this is deprecated and it /// will be removed as soon as the internal usage has transitioned successfully. /// If you are starting out building something new **do not use this**, /// instead, use [`CryptoStore`]. pub trait SyncCryptoStore: CryptoStore + Send + Sync { /// Returns all sr25519 public keys for the given key type. fn sr25519_public_keys(&self, id: KeyTypeId) -> Vec<sr25519::Public>; /// Generate a new sr25519 key pair for the given key type and an optional seed. /// /// If the given seed is `Some(_)`, the key pair will only be stored in memory. /// /// Returns the public key of the generated key pair. fn sr25519_generate_new( &self, id: KeyTypeId, seed: Option<&str>, ) -> Result<sr25519::Public, Error>; /// Returns all ed25519 public keys for the given key type. fn ed25519_public_keys(&self, id: KeyTypeId) -> Vec<ed25519::Public>; /// Generate a new ed25519 key pair for the given key type and an optional seed. /// /// If the given seed is `Some(_)`, the key pair will only be stored in memory. /// /// Returns the public key of the generated key pair. fn ed25519_generate_new( &self, id: KeyTypeId, seed: Option<&str>, ) -> Result<ed25519::Public, Error>; /// Returns all ecdsa public keys for the given key type. fn ecdsa_public_keys(&self, id: KeyTypeId) -> Vec<ecdsa::Public>; /// Generate a new ecdsa key pair for the given key type and an optional seed. /// /// If the given seed is `Some(_)`, the key pair will only be stored in memory. /// /// Returns the public key of the generated key pair. fn ecdsa_generate_new( &self, id: KeyTypeId, seed: Option<&str>, ) -> Result<ecdsa::Public, Error>; /// Insert a new key. This doesn't require any known of the crypto; but a public key must be /// manually provided. /// /// Places it into the file system store. /// /// `Err` if there's some sort of weird filesystem error, but should generally be `Ok`. fn insert_unknown(&self, key_type: KeyTypeId, suri: &str, public: &[u8]) -> Result<(), ()>; /// Find intersection between provided keys and supported keys /// /// Provided a list of (CryptoTypeId,[u8]) pairs, this would return /// a filtered set of public keys which are supported by the keystore. fn supported_keys( &self, id: KeyTypeId, keys: Vec<CryptoTypePublicPair> ) -> Result<Vec<CryptoTypePublicPair>, Error>; /// List all supported keys /// /// Returns a set of public keys the signer supports. fn keys(&self, id: KeyTypeId) -> Result<Vec<CryptoTypePublicPair>, Error> { block_on(CryptoStore::keys(self, id)) } /// Checks if the private keys for the given public key and key type combinations exist. /// /// Returns `true` iff all private keys could be found. fn has_keys(&self, public_keys: &[(Vec<u8>, KeyTypeId)]) -> bool; /// Sign with key /// /// Signs a message with the private key that matches /// the public key passed. /// /// Returns the SCALE encoded signature if key is found & supported, /// an error otherwise. fn sign_with( &self, id: KeyTypeId, key: &CryptoTypePublicPair, msg: &[u8], ) -> Result<Vec<u8>, Error>; /// Sign with any key /// /// Given a list of public keys, find the first supported key and /// sign the provided message with that key. /// /// Returns a tuple of the used key and the SCALE encoded signature. fn sign_with_any( &self, id: KeyTypeId, keys: Vec<CryptoTypePublicPair>, msg: &[u8] ) -> Result<(CryptoTypePublicPair, Vec<u8>), Error> { if keys.len() == 1 { return SyncCryptoStore::sign_with(self, id, &keys[0], msg).map(|s| (keys[0].clone(), s)); } else { for k in SyncCryptoStore::supported_keys(self, id, keys)? { if let Ok(sign) = SyncCryptoStore::sign_with(self, id, &k, msg) { return Ok((k, sign)); } } } Err(Error::KeyNotSupported(id)) } /// Sign with all keys /// /// Provided a list of public keys, sign a message with /// each key given that the key is supported. /// /// Returns a list of `Result`s each representing the SCALE encoded /// signature of each key or a Error for non-supported keys. fn sign_with_all( &self, id: KeyTypeId, keys: Vec<CryptoTypePublicPair>, msg: &[u8], ) -> Result<Vec<Result<Vec<u8>, Error>>, ()>{ Ok(keys.iter().map(|k| SyncCryptoStore::sign_with(self, id, k, msg)).collect()) } /// Generate VRF signature for given transcript data. /// /// Receives KeyTypeId and Public key to be able to map /// them to a private key that exists in the keystore which /// is, in turn, used for signing the provided transcript. /// /// Returns a result containing the signature data. /// Namely, VRFOutput and VRFProof which are returned /// inside the `VRFSignature` container struct. /// /// This function will return an error in the cases where /// the public key and key type provided do not match a private /// key in the keystore. Or, in the context of remote signing /// an error could be a network one. fn sr25519_vrf_sign( &self, key_type: KeyTypeId, public: &sr25519::Public, transcript_data: VRFTranscriptData, ) -> Result<VRFSignature, Error>; } /// A pointer to a keystore. pub type SyncCryptoStorePtr = Arc<dyn SyncCryptoStore>; sp_externalities::decl_extension! { /// The keystore extension to register/retrieve from the externalities. pub struct KeystoreExt(SyncCryptoStorePtr); }