Files
pezkuwi-subxt/substrate/primitives/keystore/src/testing.rs
T
Davide Galassi 3a90728de0 Refinements to VRF types (#14036)
* Allow extra signing data

* Fix tests after renaming

* Rename VrfSecret/VrfVerifier to VrfSecret/VrfPublic

* Further encrapsulation of 'transcript' type to the sr25519 implementation

* Keystore sr25519 pre-output

* Leave additional custom input field hidden in the associated VrfInput type

* Fix test

* More ergonomic output_bytes

* Trigger pipeline

* Define a separated type for vrf signature data

* Fix docs

* Fix doc

* Remove annotation

* Directly use dleq_proove and dleq_verify in sr25519

* Trigger CI

* Remove cruft before merge
2023-05-04 15:41:59 +02:00

360 lines
8.8 KiB
Rust

// This file is part of Substrate.
// Copyright (C) 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.
//! Types that should only be used for testing!
use crate::{Error, Keystore, KeystorePtr};
use sp_core::{
crypto::{ByteArray, KeyTypeId, Pair, VrfSecret},
ecdsa, ed25519, sr25519,
};
use parking_lot::RwLock;
use std::{collections::HashMap, sync::Arc};
/// A keystore implementation usable in tests.
#[derive(Default)]
pub struct MemoryKeystore {
/// `KeyTypeId` maps to public keys and public keys map to private keys.
keys: Arc<RwLock<HashMap<KeyTypeId, HashMap<Vec<u8>, String>>>>,
}
impl MemoryKeystore {
/// Creates a new instance of `Self`.
pub fn new() -> Self {
Self::default()
}
fn pair<T: Pair>(&self, key_type: KeyTypeId, public: &T::Public) -> Option<T> {
self.keys.read().get(&key_type).and_then(|inner| {
inner
.get(public.as_slice())
.map(|s| T::from_string(s, None).expect("seed slice is valid"))
})
}
fn public_keys<T: Pair>(&self, key_type: KeyTypeId) -> Vec<T::Public> {
self.keys
.read()
.get(&key_type)
.map(|keys| {
keys.values()
.map(|s| T::from_string(s, None).expect("seed slice is valid"))
.map(|p| p.public())
.collect()
})
.unwrap_or_default()
}
fn generate_new<T: Pair>(
&self,
key_type: KeyTypeId,
seed: Option<&str>,
) -> Result<T::Public, Error> {
match seed {
Some(seed) => {
let pair = T::from_string(seed, None)
.map_err(|_| Error::ValidationError("Generates a pair.".to_owned()))?;
self.keys
.write()
.entry(key_type)
.or_default()
.insert(pair.public().to_raw_vec(), seed.into());
Ok(pair.public())
},
None => {
let (pair, phrase, _) = T::generate_with_phrase(None);
self.keys
.write()
.entry(key_type)
.or_default()
.insert(pair.public().to_raw_vec(), phrase);
Ok(pair.public())
},
}
}
fn sign<T: Pair>(
&self,
key_type: KeyTypeId,
public: &T::Public,
msg: &[u8],
) -> Result<Option<T::Signature>, Error> {
let sig = self.pair::<T>(key_type, public).map(|pair| pair.sign(msg));
Ok(sig)
}
fn vrf_sign<T: Pair + VrfSecret>(
&self,
key_type: KeyTypeId,
public: &T::Public,
data: &T::VrfSignData,
) -> Result<Option<T::VrfSignature>, Error> {
let sig = self.pair::<T>(key_type, public).map(|pair| pair.vrf_sign(data));
Ok(sig)
}
fn vrf_output<T: Pair + VrfSecret>(
&self,
key_type: KeyTypeId,
public: &T::Public,
input: &T::VrfInput,
) -> Result<Option<T::VrfOutput>, Error> {
let preout = self.pair::<T>(key_type, public).map(|pair| pair.vrf_output(input));
Ok(preout)
}
}
impl Keystore for MemoryKeystore {
fn sr25519_public_keys(&self, key_type: KeyTypeId) -> Vec<sr25519::Public> {
self.public_keys::<sr25519::Pair>(key_type)
}
fn sr25519_generate_new(
&self,
key_type: KeyTypeId,
seed: Option<&str>,
) -> Result<sr25519::Public, Error> {
self.generate_new::<sr25519::Pair>(key_type, seed)
}
fn sr25519_sign(
&self,
key_type: KeyTypeId,
public: &sr25519::Public,
msg: &[u8],
) -> Result<Option<sr25519::Signature>, Error> {
self.sign::<sr25519::Pair>(key_type, public, msg)
}
fn sr25519_vrf_sign(
&self,
key_type: KeyTypeId,
public: &sr25519::Public,
data: &sr25519::vrf::VrfSignData,
) -> Result<Option<sr25519::vrf::VrfSignature>, Error> {
self.vrf_sign::<sr25519::Pair>(key_type, public, data)
}
fn sr25519_vrf_output(
&self,
key_type: KeyTypeId,
public: &sr25519::Public,
input: &sr25519::vrf::VrfInput,
) -> Result<Option<sr25519::vrf::VrfOutput>, Error> {
self.vrf_output::<sr25519::Pair>(key_type, public, input)
}
fn ed25519_public_keys(&self, key_type: KeyTypeId) -> Vec<ed25519::Public> {
self.public_keys::<ed25519::Pair>(key_type)
}
fn ed25519_generate_new(
&self,
key_type: KeyTypeId,
seed: Option<&str>,
) -> Result<ed25519::Public, Error> {
self.generate_new::<ed25519::Pair>(key_type, seed)
}
fn ed25519_sign(
&self,
key_type: KeyTypeId,
public: &ed25519::Public,
msg: &[u8],
) -> Result<Option<ed25519::Signature>, Error> {
self.sign::<ed25519::Pair>(key_type, public, msg)
}
fn ecdsa_public_keys(&self, key_type: KeyTypeId) -> Vec<ecdsa::Public> {
self.public_keys::<ecdsa::Pair>(key_type)
}
fn ecdsa_generate_new(
&self,
key_type: KeyTypeId,
seed: Option<&str>,
) -> Result<ecdsa::Public, Error> {
self.generate_new::<ecdsa::Pair>(key_type, seed)
}
fn ecdsa_sign(
&self,
key_type: KeyTypeId,
public: &ecdsa::Public,
msg: &[u8],
) -> Result<Option<ecdsa::Signature>, Error> {
self.sign::<ecdsa::Pair>(key_type, public, msg)
}
fn ecdsa_sign_prehashed(
&self,
key_type: KeyTypeId,
public: &ecdsa::Public,
msg: &[u8; 32],
) -> Result<Option<ecdsa::Signature>, Error> {
let sig = self.pair::<ecdsa::Pair>(key_type, public).map(|pair| pair.sign_prehashed(msg));
Ok(sig)
}
fn insert(&self, key_type: KeyTypeId, suri: &str, public: &[u8]) -> Result<(), ()> {
self.keys
.write()
.entry(key_type)
.or_default()
.insert(public.to_owned(), suri.to_string());
Ok(())
}
fn keys(&self, key_type: KeyTypeId) -> Result<Vec<Vec<u8>>, Error> {
let keys = self
.keys
.read()
.get(&key_type)
.map(|map| map.keys().cloned().collect())
.unwrap_or_default();
Ok(keys)
}
fn has_keys(&self, public_keys: &[(Vec<u8>, KeyTypeId)]) -> bool {
public_keys
.iter()
.all(|(k, t)| self.keys.read().get(t).and_then(|s| s.get(k)).is_some())
}
}
impl Into<KeystorePtr> for MemoryKeystore {
fn into(self) -> KeystorePtr {
Arc::new(self)
}
}
#[cfg(test)]
mod tests {
use super::*;
use sp_core::{
sr25519,
testing::{ECDSA, ED25519, SR25519},
};
#[test]
fn store_key_and_extract() {
let store = MemoryKeystore::new();
let public = store.ed25519_generate_new(ED25519, None).expect("Generates key");
let public_keys = store.ed25519_public_keys(ED25519);
assert!(public_keys.contains(&public.into()));
}
#[test]
fn store_unknown_and_extract_it() {
let store = MemoryKeystore::new();
let secret_uri = "//Alice";
let key_pair = sr25519::Pair::from_string(secret_uri, None).expect("Generates key pair");
store
.insert(SR25519, secret_uri, key_pair.public().as_ref())
.expect("Inserts unknown key");
let public_keys = store.sr25519_public_keys(SR25519);
assert!(public_keys.contains(&key_pair.public().into()));
}
#[test]
fn vrf_sign() {
let store = MemoryKeystore::new();
let secret_uri = "//Alice";
let key_pair = sr25519::Pair::from_string(secret_uri, None).expect("Generates key pair");
let data = sr25519::vrf::VrfInput::new(
b"Test",
&[
(b"one", &1_u64.to_le_bytes()),
(b"two", &2_u64.to_le_bytes()),
(b"three", "test".as_bytes()),
],
)
.into_sign_data();
let result = store.sr25519_vrf_sign(SR25519, &key_pair.public(), &data);
assert!(result.unwrap().is_none());
store
.insert(SR25519, secret_uri, key_pair.public().as_ref())
.expect("Inserts unknown key");
let result = store.sr25519_vrf_sign(SR25519, &key_pair.public(), &data);
assert!(result.unwrap().is_some());
}
#[test]
fn vrf_output() {
let store = MemoryKeystore::new();
let secret_uri = "//Alice";
let pair = sr25519::Pair::from_string(secret_uri, None).expect("Generates key pair");
let input = sr25519::vrf::VrfInput::new(
b"Test",
&[
(b"one", &1_u64.to_le_bytes()),
(b"two", &2_u64.to_le_bytes()),
(b"three", "test".as_bytes()),
],
);
let result = store.sr25519_vrf_output(SR25519, &pair.public(), &input);
assert!(result.unwrap().is_none());
store
.insert(SR25519, secret_uri, pair.public().as_ref())
.expect("Inserts unknown key");
let preout = store.sr25519_vrf_output(SR25519, &pair.public(), &input).unwrap().unwrap();
let result = preout.make_bytes::<32>(b"rand", &input, &pair.public());
assert!(result.is_ok());
}
#[test]
fn ecdsa_sign_prehashed_works() {
let store = MemoryKeystore::new();
let suri = "//Alice";
let pair = ecdsa::Pair::from_string(suri, None).unwrap();
let msg = sp_core::keccak_256(b"this should be a hashed message");
// no key in key store
let res = store.ecdsa_sign_prehashed(ECDSA, &pair.public(), &msg).unwrap();
assert!(res.is_none());
// insert key, sign again
store.insert(ECDSA, suri, pair.public().as_ref()).unwrap();
let res = store.ecdsa_sign_prehashed(ECDSA, &pair.public(), &msg).unwrap();
assert!(res.is_some());
}
}