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//! Merging `KeyStore` and `Userstore` into the same concept
use super::rights::Access;
use std::collections::HashMap;
use traits::AutoEncoder;
/// A thin user UserStore
///
/// It's implementation can manage multiple keys per user, of various
/// types and constrained for limited access rights.
#[derive(Serialize, Deserialize)]
pub struct UserStore {
store: HashMap<String, StoreUser>,
}
/// Internal store user structure
#[derive(Serialize, Deserialize)]
pub struct StoreUser {
name: String,
keys: HashMap<Access, Vec<u8>>,
}
impl AutoEncoder for UserStore {}
impl UserStore {
/// Create a new, empty UserStore
///
/// This is most likely *not* what you want. Instead, transform
/// a `MetaData` object into a UserStore.
pub fn new() -> Self {
Self {
store: HashMap::new(),
}
}
/// Adds a new user to the store, with a root-key
pub fn add_user(&mut self, name: String, key: Vec<u8>) {
let mut user = StoreUser {
name: name.clone(),
keys: HashMap::new(),
};
user.keys.insert(Access::Root, key);
self.store.insert(name, user);
}
/// Delete a user from this store
pub fn del_user(&mut self, name: &str) {
self.store.remove(name);
}
/// Add a key to an existing user
pub fn add_key(&mut self, user: String, k: Vec<u8>, access: Access) {
if !self.store.contains_key(&user) {
return;
}
self.store.get_mut(&user).unwrap().keys.insert(access, k);
}
pub fn get_root_key(&self, user: &str) -> Option<&Vec<u8>> {
self.store
.get(user)
.map_or(None, |u| u.keys.get(&Access::Root))
}
pub fn get_key(&self, user: &str, access: Access) -> Option<&Vec<u8>> {
self.store.get(user).map_or(None, |u| u.keys.get(&access))
}
}
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