1
0
Fork 0
mirror of https://github.com/denoland/deno.git synced 2024-12-11 01:58:05 -05:00
denoland-deno/cli/cache/cache_db.rs
Matt Mastracci c65149c0a0
fix(core): restore cache journal mode to TRUNCATE and tweak tokio test in CacheDB (#18469)
Fast-follow on #18401 -- the reason that some tests were panicking in
the `CacheDB` `impl Drop` was that the cache itself was being dropped
during panic and the runtime may or may not still exist at that point.
We can reduce the actual tokio runtime testing to where it's needed.

In addition, we return the journal mode to `TRUNCATE` to avoid the risk
of data corruption.
2023-03-28 14:06:57 -06:00

485 lines
14 KiB
Rust

// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license.
use deno_core::error::AnyError;
use deno_core::parking_lot::Mutex;
use deno_core::parking_lot::MutexGuard;
use deno_runtime::deno_webstorage::rusqlite;
use deno_runtime::deno_webstorage::rusqlite::Connection;
use deno_runtime::deno_webstorage::rusqlite::OptionalExtension;
use deno_runtime::deno_webstorage::rusqlite::Params;
use once_cell::sync::OnceCell;
use std::path::PathBuf;
use std::sync::Arc;
/// What should the cache should do on failure?
#[derive(Default)]
pub enum CacheFailure {
/// Return errors if failure mode otherwise unspecified.
#[default]
Error,
/// Create an in-memory cache that is not persistent.
InMemory,
/// Create a blackhole cache that ignores writes and returns empty reads.
Blackhole,
}
/// Configuration SQL and other parameters for a [`CacheDB`].
pub struct CacheDBConfiguration {
/// SQL to run for a new database.
pub table_initializer: &'static str,
/// SQL to run when the version from [`crate::version::deno()`] changes.
pub on_version_change: &'static str,
/// Prepared statements to pre-heat while initializing the database.
pub preheat_queries: &'static [&'static str],
/// What the cache should do on failure.
pub on_failure: CacheFailure,
}
impl CacheDBConfiguration {
fn create_combined_sql(&self) -> String {
format!(
"
PRAGMA journal_mode=TRUNCATE;
PRAGMA synchronous=NORMAL;
PRAGMA temp_store=memory;
PRAGMA page_size=4096;
PRAGMA mmap_size=6000000;
PRAGMA optimize;
CREATE TABLE IF NOT EXISTS info (
key TEXT PRIMARY KEY,
value TEXT NOT NULL
);
{}
",
self.table_initializer
)
}
}
enum ConnectionState {
Connected(Connection),
Blackhole,
Error(Arc<AnyError>),
}
/// A cache database that eagerly initializes itself off-thread, preventing initialization operations
/// from blocking the main thread.
#[derive(Clone)]
pub struct CacheDB {
// TODO(mmastrac): We can probably simplify our thread-safe implementation here
conn: Arc<Mutex<OnceCell<ConnectionState>>>,
path: Option<PathBuf>,
config: &'static CacheDBConfiguration,
version: &'static str,
}
impl Drop for CacheDB {
fn drop(&mut self) {
// No need to clean up an in-memory cache in an way -- just drop and go.
let path = match self.path.take() {
Some(path) => path,
_ => return,
};
// If Deno is panicking, tokio is sometimes gone before we have a chance to shutdown. In
// that case, we just allow the drop to happen as expected.
if tokio::runtime::Handle::try_current().is_err() {
return;
}
// For on-disk caches, see if we're the last holder of the Arc.
let arc = std::mem::take(&mut self.conn);
if let Ok(inner) = Arc::try_unwrap(arc) {
// Hand off SQLite connection to another thread to do the surprisingly expensive cleanup
let inner = inner.into_inner().into_inner();
if let Some(conn) = inner {
tokio::task::spawn_blocking(move || {
drop(conn);
log::trace!(
"Cleaned up SQLite connection at {}",
path.to_string_lossy()
);
});
}
}
}
}
impl CacheDB {
#[cfg(test)]
pub fn in_memory(
config: &'static CacheDBConfiguration,
version: &'static str,
) -> Self {
CacheDB {
conn: Arc::new(Mutex::new(OnceCell::new())),
path: None,
config,
version,
}
}
pub fn from_path(
config: &'static CacheDBConfiguration,
path: PathBuf,
version: &'static str,
) -> Self {
log::debug!("Opening cache {}...", path.to_string_lossy());
let new = Self {
conn: Arc::new(Mutex::new(OnceCell::new())),
path: Some(path),
config,
version,
};
new.spawn_eager_init_thread();
new
}
/// Useful for testing: re-create this cache DB with a different current version.
#[cfg(test)]
pub(crate) fn recreate_with_version(mut self, version: &'static str) -> Self {
// By taking the lock, we know there are no initialization threads alive
drop(self.conn.lock());
let arc = std::mem::take(&mut self.conn);
let conn = match Arc::try_unwrap(arc) {
Err(_) => panic!("Failed to unwrap connection"),
Ok(conn) => match conn.into_inner().into_inner() {
Some(ConnectionState::Connected(conn)) => conn,
_ => panic!("Connection had failed and cannot be unwrapped"),
},
};
Self::initialize_connection(self.config, &conn, version).unwrap();
let cell = OnceCell::new();
_ = cell.set(ConnectionState::Connected(conn));
Self {
conn: Arc::new(Mutex::new(cell)),
path: self.path.clone(),
config: self.config,
version,
}
}
fn spawn_eager_init_thread(&self) {
let clone = self.clone();
debug_assert!(tokio::runtime::Handle::try_current().is_ok());
tokio::task::spawn_blocking(move || {
let lock = clone.conn.lock();
clone.initialize(&lock);
});
}
/// Open the connection in memory or on disk.
fn actually_open_connection(
&self,
path: &Option<PathBuf>,
) -> Result<Connection, rusqlite::Error> {
match path {
// This should never fail unless something is very wrong
None => Connection::open_in_memory(),
Some(path) => Connection::open(path),
}
}
/// Attempt to initialize that connection.
fn initialize_connection(
config: &CacheDBConfiguration,
conn: &Connection,
version: &str,
) -> Result<(), AnyError> {
let sql = config.create_combined_sql();
conn.execute_batch(&sql)?;
// Check the version
let existing_version = conn
.query_row(
"SELECT value FROM info WHERE key='CLI_VERSION' LIMIT 1",
[],
|row| row.get::<_, String>(0),
)
.optional()?
.unwrap_or_default();
// If Deno has been upgraded, run the SQL to update the version
if existing_version != version {
conn.execute_batch(config.on_version_change)?;
let mut stmt = conn
.prepare("INSERT OR REPLACE INTO info (key, value) VALUES (?1, ?2)")?;
stmt.execute(["CLI_VERSION", version])?;
}
// Preheat any prepared queries
for preheat in config.preheat_queries {
drop(conn.prepare_cached(preheat)?);
}
Ok(())
}
/// Open and initialize a connection.
fn open_connection_and_init(
&self,
path: &Option<PathBuf>,
) -> Result<Connection, AnyError> {
let conn = self.actually_open_connection(path)?;
Self::initialize_connection(self.config, &conn, self.version)?;
Ok(conn)
}
/// This function represents the policy for dealing with corrupted cache files. We try fairly aggressively
/// to repair the situation, and if we can't, we prefer to log noisily and continue with in-memory caches.
fn open_connection(&self) -> Result<ConnectionState, AnyError> {
// Success on first try? We hope that this is the case.
let err = match self.open_connection_and_init(&self.path) {
Ok(conn) => return Ok(ConnectionState::Connected(conn)),
Err(err) => err,
};
if self.path.is_none() {
// If an in-memory DB fails, that's game over
log::error!("Failed to initialize in-memory cache database.");
return Err(err);
}
let path = self.path.as_ref().unwrap();
// There are rare times in the tests when we can't initialize a cache DB the first time, but it succeeds the second time, so
// we don't log these at a debug level.
log::trace!(
"Could not initialize cache database '{}', retrying... ({err:?})",
path.to_string_lossy(),
);
// Try a second time
let err = match self.open_connection_and_init(&self.path) {
Ok(conn) => return Ok(ConnectionState::Connected(conn)),
Err(err) => err,
};
// Failed, try deleting it
log::warn!(
"Could not initialize cache database '{}', deleting and retrying... ({err:?})",
path.to_string_lossy()
);
if std::fs::remove_file(path).is_ok() {
// Try a third time if we successfully deleted it
let res = self.open_connection_and_init(&self.path);
if let Ok(conn) = res {
return Ok(ConnectionState::Connected(conn));
};
}
match self.config.on_failure {
CacheFailure::InMemory => {
log::error!(
"Failed to open cache file '{}', opening in-memory cache.",
path.to_string_lossy()
);
Ok(ConnectionState::Connected(
self.open_connection_and_init(&None)?,
))
}
CacheFailure::Blackhole => {
log::error!(
"Failed to open cache file '{}', performance may be degraded.",
path.to_string_lossy()
);
Ok(ConnectionState::Blackhole)
}
CacheFailure::Error => {
log::error!(
"Failed to open cache file '{}', expect further errors.",
path.to_string_lossy()
);
Err(err)
}
}
}
fn initialize<'a>(
&self,
lock: &'a MutexGuard<OnceCell<ConnectionState>>,
) -> &'a ConnectionState {
lock.get_or_init(|| match self.open_connection() {
Ok(conn) => conn,
Err(e) => ConnectionState::Error(e.into()),
})
}
pub fn with_connection<T: Default>(
&self,
f: impl FnOnce(&Connection) -> Result<T, AnyError>,
) -> Result<T, AnyError> {
let lock = self.conn.lock();
let conn = self.initialize(&lock);
match conn {
ConnectionState::Blackhole => {
// Cache is a blackhole - nothing in or out.
Ok(T::default())
}
ConnectionState::Error(e) => {
// This isn't ideal because we lose the original underlying error
let err = AnyError::msg(e.clone().to_string());
Err(err)
}
ConnectionState::Connected(conn) => f(conn),
}
}
#[cfg(test)]
pub fn ensure_connected(&self) -> Result<(), AnyError> {
self.with_connection(|_| Ok(()))
}
pub fn execute(
&self,
sql: &'static str,
params: impl Params,
) -> Result<usize, AnyError> {
self.with_connection(|conn| {
let mut stmt = conn.prepare_cached(sql)?;
let res = stmt.execute(params)?;
Ok(res)
})
}
pub fn exists(
&self,
sql: &'static str,
params: impl Params,
) -> Result<bool, AnyError> {
self.with_connection(|conn| {
let mut stmt = conn.prepare_cached(sql)?;
let res = stmt.exists(params)?;
Ok(res)
})
}
/// Query a row from the database with a mapping function.
pub fn query_row<T, F>(
&self,
sql: &'static str,
params: impl Params,
f: F,
) -> Result<Option<T>, AnyError>
where
F: FnOnce(&rusqlite::Row<'_>) -> Result<T, AnyError>,
{
let res = self.with_connection(|conn| {
let mut stmt = conn.prepare_cached(sql)?;
let mut rows = stmt.query(params)?;
if let Some(row) = rows.next()? {
let res = f(row)?;
Ok(Some(res))
} else {
Ok(None)
}
})?;
Ok(res)
}
}
#[cfg(test)]
mod tests {
use super::*;
static TEST_DB: CacheDBConfiguration = CacheDBConfiguration {
table_initializer: "create table if not exists test(value TEXT);",
on_version_change: "delete from test;",
preheat_queries: &[],
on_failure: CacheFailure::InMemory,
};
static TEST_DB_BLACKHOLE: CacheDBConfiguration = CacheDBConfiguration {
table_initializer: "create table if not exists test(value TEXT);",
on_version_change: "delete from test;",
preheat_queries: &[],
on_failure: CacheFailure::Blackhole,
};
static TEST_DB_ERROR: CacheDBConfiguration = CacheDBConfiguration {
table_initializer: "create table if not exists test(value TEXT);",
on_version_change: "delete from test;",
preheat_queries: &[],
on_failure: CacheFailure::Error,
};
static BAD_SQL_TEST_DB: CacheDBConfiguration = CacheDBConfiguration {
table_initializer: "bad sql;",
on_version_change: "delete from test;",
preheat_queries: &[],
on_failure: CacheFailure::InMemory,
};
static FAILURE_PATH: &str = "/tmp/this/doesnt/exist/so/will/always/fail";
#[tokio::test]
async fn simple_database() {
let db = CacheDB::in_memory(&TEST_DB, "1.0");
db.ensure_connected()
.expect("Failed to initialize in-memory database");
db.execute("insert into test values (?1)", [1]).unwrap();
let res = db
.query_row("select * from test", [], |row| {
Ok(row.get::<_, String>(0).unwrap())
})
.unwrap();
assert_eq!(Some("1".into()), res);
}
#[tokio::test]
async fn bad_sql() {
let db = CacheDB::in_memory(&BAD_SQL_TEST_DB, "1.0");
db.ensure_connected()
.expect_err("Expected to fail, but succeeded");
}
#[tokio::test]
async fn failure_mode_in_memory() {
let db = CacheDB::from_path(&TEST_DB, FAILURE_PATH.into(), "1.0");
db.ensure_connected()
.expect("Should have created a database");
db.execute("insert into test values (?1)", [1]).unwrap();
let res = db
.query_row("select * from test", [], |row| {
Ok(row.get::<_, String>(0).unwrap())
})
.unwrap();
assert_eq!(Some("1".into()), res);
}
#[tokio::test]
async fn failure_mode_blackhole() {
let db = CacheDB::from_path(&TEST_DB_BLACKHOLE, FAILURE_PATH.into(), "1.0");
db.ensure_connected()
.expect("Should have created a database");
db.execute("insert into test values (?1)", [1]).unwrap();
let res = db
.query_row("select * from test", [], |row| {
Ok(row.get::<_, String>(0).unwrap())
})
.unwrap();
assert_eq!(None, res);
}
#[tokio::test]
async fn failure_mode_error() {
let db = CacheDB::from_path(&TEST_DB_ERROR, FAILURE_PATH.into(), "1.0");
db.ensure_connected().expect_err("Should have failed");
db.execute("insert into test values (?1)", [1])
.expect_err("Should have failed");
db.query_row("select * from test", [], |row| {
Ok(row.get::<_, String>(0).unwrap())
})
.expect_err("Should have failed");
}
}