meilisearch/meilisearch-auth/src/store.rs

257 lines
7.9 KiB
Rust

use enum_iterator::IntoEnumIterator;
use std::borrow::Cow;
use std::cmp::Reverse;
use std::convert::TryFrom;
use std::convert::TryInto;
use std::fs::create_dir_all;
use std::path::Path;
use std::str;
use std::sync::Arc;
use heed::types::{ByteSlice, DecodeIgnore, SerdeJson};
use heed::{Database, Env, EnvOpenOptions, RwTxn};
use time::OffsetDateTime;
use super::error::Result;
use super::{Action, Key};
const AUTH_STORE_SIZE: usize = 1_073_741_824; //1GiB
pub const KEY_ID_LENGTH: usize = 8;
const AUTH_DB_PATH: &str = "auth";
const KEY_DB_NAME: &str = "api-keys";
const KEY_ID_ACTION_INDEX_EXPIRATION_DB_NAME: &str = "keyid-action-index-expiration";
pub type KeyId = [u8; KEY_ID_LENGTH];
#[derive(Clone)]
pub struct HeedAuthStore {
env: Arc<Env>,
keys: Database<ByteSlice, SerdeJson<Key>>,
action_keyid_index_expiration: Database<KeyIdActionCodec, SerdeJson<Option<OffsetDateTime>>>,
should_close_on_drop: bool,
}
impl Drop for HeedAuthStore {
fn drop(&mut self) {
if self.should_close_on_drop && Arc::strong_count(&self.env) == 1 {
self.env.as_ref().clone().prepare_for_closing();
}
}
}
pub fn open_auth_store_env(path: &Path) -> heed::Result<heed::Env> {
let mut options = EnvOpenOptions::new();
options.map_size(AUTH_STORE_SIZE); // 1GB
options.max_dbs(2);
options.open(path)
}
impl HeedAuthStore {
pub fn new(path: impl AsRef<Path>) -> Result<Self> {
let path = path.as_ref().join(AUTH_DB_PATH);
create_dir_all(&path)?;
let env = Arc::new(open_auth_store_env(path.as_ref())?);
let keys = env.create_database(Some(KEY_DB_NAME))?;
let action_keyid_index_expiration =
env.create_database(Some(KEY_ID_ACTION_INDEX_EXPIRATION_DB_NAME))?;
Ok(Self {
env,
keys,
action_keyid_index_expiration,
should_close_on_drop: true,
})
}
pub fn set_drop_on_close(&mut self, v: bool) {
self.should_close_on_drop = v;
}
pub fn is_empty(&self) -> Result<bool> {
let rtxn = self.env.read_txn()?;
Ok(self.keys.len(&rtxn)? == 0)
}
pub fn put_api_key(&self, key: Key) -> Result<Key> {
let mut wtxn = self.env.write_txn()?;
self.keys.put(&mut wtxn, &key.id, &key)?;
let id = key.id;
// delete key from inverted database before refilling it.
self.delete_key_from_inverted_db(&mut wtxn, &id)?;
// create inverted database.
let db = self.action_keyid_index_expiration;
let actions = if key.actions.contains(&Action::All) {
// if key.actions contains All, we iterate over all actions.
Action::into_enum_iter().collect()
} else {
key.actions.clone()
};
let no_index_restriction = key.indexes.contains(&"*".to_owned());
for action in actions {
if no_index_restriction {
// If there is no index restriction we put None.
db.put(&mut wtxn, &(&id, &action, None), &key.expires_at)?;
} else {
// else we create a key for each index.
for index in key.indexes.iter() {
db.put(
&mut wtxn,
&(&id, &action, Some(index.as_bytes())),
&key.expires_at,
)?;
}
}
}
wtxn.commit()?;
Ok(key)
}
pub fn get_api_key(&self, key: impl AsRef<str>) -> Result<Option<Key>> {
let rtxn = self.env.read_txn()?;
match self.get_key_id(key.as_ref().as_bytes()) {
Some(id) => self.keys.get(&rtxn, &id).map_err(|e| e.into()),
None => Ok(None),
}
}
pub fn delete_api_key(&self, key: impl AsRef<str>) -> Result<bool> {
let mut wtxn = self.env.write_txn()?;
let existing = match self.get_key_id(key.as_ref().as_bytes()) {
Some(id) => {
let existing = self.keys.delete(&mut wtxn, &id)?;
self.delete_key_from_inverted_db(&mut wtxn, &id)?;
existing
}
None => false,
};
wtxn.commit()?;
Ok(existing)
}
pub fn list_api_keys(&self) -> Result<Vec<Key>> {
let mut list = Vec::new();
let rtxn = self.env.read_txn()?;
for result in self.keys.remap_key_type::<DecodeIgnore>().iter(&rtxn)? {
let (_, content) = result?;
list.push(content);
}
list.sort_unstable_by_key(|k| Reverse(k.created_at));
Ok(list)
}
pub fn get_expiration_date(
&self,
key: &[u8],
action: Action,
index: Option<&[u8]>,
) -> Result<Option<Option<OffsetDateTime>>> {
let rtxn = self.env.read_txn()?;
match self.get_key_id(key) {
Some(id) => {
let tuple = (&id, &action, index);
Ok(self.action_keyid_index_expiration.get(&rtxn, &tuple)?)
}
None => Ok(None),
}
}
pub fn prefix_first_expiration_date(
&self,
key: &[u8],
action: Action,
) -> Result<Option<Option<OffsetDateTime>>> {
let rtxn = self.env.read_txn()?;
match self.get_key_id(key) {
Some(id) => {
let tuple = (&id, &action, None);
Ok(self
.action_keyid_index_expiration
.prefix_iter(&rtxn, &tuple)?
.next()
.transpose()?
.map(|(_, expiration)| expiration))
}
None => Ok(None),
}
}
pub fn get_key_id(&self, key: &[u8]) -> Option<KeyId> {
try_split_array_at::<_, KEY_ID_LENGTH>(key).map(|(id, _)| *id)
}
fn delete_key_from_inverted_db(&self, wtxn: &mut RwTxn, key: &KeyId) -> Result<()> {
let mut iter = self
.action_keyid_index_expiration
.remap_types::<ByteSlice, DecodeIgnore>()
.prefix_iter_mut(wtxn, key)?;
while iter.next().transpose()?.is_some() {
// safety: we don't keep references from inside the LMDB database.
unsafe { iter.del_current()? };
}
Ok(())
}
}
/// Codec allowing to retrieve the expiration date of an action,
/// optionnally on a spcific index, for a given key.
pub struct KeyIdActionCodec;
impl<'a> heed::BytesDecode<'a> for KeyIdActionCodec {
type DItem = (KeyId, Action, Option<&'a [u8]>);
fn bytes_decode(bytes: &'a [u8]) -> Option<Self::DItem> {
let (key_id, action_bytes) = try_split_array_at(bytes)?;
let (action_bytes, index) = match try_split_array_at(action_bytes)? {
(action, []) => (action, None),
(action, index) => (action, Some(index)),
};
let action = Action::from_repr(u8::from_be_bytes(*action_bytes))?;
Some((*key_id, action, index))
}
}
impl<'a> heed::BytesEncode<'a> for KeyIdActionCodec {
type EItem = (&'a KeyId, &'a Action, Option<&'a [u8]>);
fn bytes_encode((key_id, action, index): &Self::EItem) -> Option<Cow<[u8]>> {
let mut bytes = Vec::new();
bytes.extend_from_slice(*key_id);
let action_bytes = u8::to_be_bytes(action.repr());
bytes.extend_from_slice(&action_bytes);
if let Some(index) = index {
bytes.extend_from_slice(index);
}
Some(Cow::Owned(bytes))
}
}
/// Divides one slice into two at an index, returns `None` if mid is out of bounds.
pub fn try_split_at<T>(slice: &[T], mid: usize) -> Option<(&[T], &[T])> {
if mid <= slice.len() {
Some(slice.split_at(mid))
} else {
None
}
}
/// Divides one slice into an array and the tail at an index,
/// returns `None` if `N` is out of bounds.
pub fn try_split_array_at<T, const N: usize>(slice: &[T]) -> Option<(&[T; N], &[T])>
where
[T; N]: for<'a> TryFrom<&'a [T]>,
{
let (head, tail) = try_split_at(slice, N)?;
let head = head.try_into().ok()?;
Some((head, tail))
}