//! Prepared statements cache for faster execution. use crate::raw_statement::RawStatement; use crate::{Connection, Result, Statement}; use hashlink::LruCache; use std::cell::RefCell; use std::ops::{Deref, DerefMut}; use std::sync::Arc; impl Connection { /// Prepare a SQL statement for execution, returning a previously prepared /// (but not currently in-use) statement if one is available. The /// returned statement will be cached for reuse by future calls to /// [`prepare_cached`](Connection::prepare_cached) once it is dropped. /// /// ```rust,no_run /// # use rusqlite::{Connection, Result}; /// fn insert_new_people(conn: &Connection) -> Result<()> { /// { /// let mut stmt = conn.prepare_cached("INSERT INTO People (name) VALUES (?)")?; /// stmt.execute(["Joe Smith"])?; /// } /// { /// // This will return the same underlying SQLite statement handle without /// // having to prepare it again. /// let mut stmt = conn.prepare_cached("INSERT INTO People (name) VALUES (?)")?; /// stmt.execute(["Bob Jones"])?; /// } /// Ok(()) /// } /// ``` /// /// # Failure /// /// Will return `Err` if `sql` cannot be converted to a C-compatible string /// or if the underlying SQLite call fails. #[inline] pub fn prepare_cached(&self, sql: &str) -> Result> { self.cache.get(self, sql) } /// Set the maximum number of cached prepared statements this connection /// will hold. By default, a connection will hold a relatively small /// number of cached statements. If you need more, or know that you /// will not use cached statements, you /// can set the capacity manually using this method. #[inline] pub fn set_prepared_statement_cache_capacity(&self, capacity: usize) { self.cache.set_capacity(capacity); } /// Remove/finalize all prepared statements currently in the cache. #[inline] pub fn flush_prepared_statement_cache(&self) { self.cache.flush(); } } /// Prepared statements LRU cache. // #[derive(Debug)] // FIXME: https://github.com/kyren/hashlink/pull/4 pub struct StatementCache(RefCell, RawStatement>>); #[allow(clippy::non_send_fields_in_send_ty)] unsafe impl Send for StatementCache {} /// Cacheable statement. /// /// Statement will return automatically to the cache by default. /// If you want the statement to be discarded, call /// [`discard()`](CachedStatement::discard) on it. pub struct CachedStatement<'conn> { stmt: Option>, cache: &'conn StatementCache, } impl<'conn> Deref for CachedStatement<'conn> { type Target = Statement<'conn>; #[inline] fn deref(&self) -> &Statement<'conn> { self.stmt.as_ref().unwrap() } } impl<'conn> DerefMut for CachedStatement<'conn> { #[inline] fn deref_mut(&mut self) -> &mut Statement<'conn> { self.stmt.as_mut().unwrap() } } impl Drop for CachedStatement<'_> { #[allow(unused_must_use)] #[inline] fn drop(&mut self) { if let Some(stmt) = self.stmt.take() { self.cache.cache_stmt(unsafe { stmt.into_raw() }); } } } impl CachedStatement<'_> { #[inline] fn new<'conn>(stmt: Statement<'conn>, cache: &'conn StatementCache) -> CachedStatement<'conn> { CachedStatement { stmt: Some(stmt), cache, } } /// Discard the statement, preventing it from being returned to its /// [`Connection`]'s collection of cached statements. #[inline] pub fn discard(mut self) { self.stmt = None; } } impl StatementCache { /// Create a statement cache. #[inline] pub fn with_capacity(capacity: usize) -> StatementCache { StatementCache(RefCell::new(LruCache::new(capacity))) } #[inline] fn set_capacity(&self, capacity: usize) { self.0.borrow_mut().set_capacity(capacity); } // Search the cache for a prepared-statement object that implements `sql`. // If no such prepared-statement can be found, allocate and prepare a new one. // // # Failure // // Will return `Err` if no cached statement can be found and the underlying // SQLite prepare call fails. fn get<'conn>( &'conn self, conn: &'conn Connection, sql: &str, ) -> Result> { let trimmed = sql.trim(); let mut cache = self.0.borrow_mut(); let stmt = match cache.remove(trimmed) { Some(raw_stmt) => Ok(Statement::new(conn, raw_stmt)), None => conn.prepare(trimmed), }; stmt.map(|mut stmt| { stmt.stmt.set_statement_cache_key(trimmed); CachedStatement::new(stmt, self) }) } // Return a statement to the cache. fn cache_stmt(&self, stmt: RawStatement) { if stmt.is_null() { return; } let mut cache = self.0.borrow_mut(); stmt.clear_bindings(); if let Some(sql) = stmt.statement_cache_key() { cache.insert(sql, stmt); } else { debug_assert!( false, "bug in statement cache code, statement returned to cache that without key" ); } } #[inline] fn flush(&self) { let mut cache = self.0.borrow_mut(); cache.clear(); } } #[cfg(test)] mod test { use super::StatementCache; use crate::{Connection, Result}; use fallible_iterator::FallibleIterator; impl StatementCache { fn clear(&self) { self.0.borrow_mut().clear(); } fn len(&self) -> usize { self.0.borrow().len() } fn capacity(&self) -> usize { self.0.borrow().capacity() } } #[test] fn test_cache() -> Result<()> { let db = Connection::open_in_memory()?; let cache = &db.cache; let initial_capacity = cache.capacity(); assert_eq!(0, cache.len()); assert!(initial_capacity > 0); let sql = "PRAGMA schema_version"; { let mut stmt = db.prepare_cached(sql)?; assert_eq!(0, cache.len()); assert_eq!(0, stmt.query_row([], |r| r.get::<_, i64>(0))?); } assert_eq!(1, cache.len()); { let mut stmt = db.prepare_cached(sql)?; assert_eq!(0, cache.len()); assert_eq!(0, stmt.query_row([], |r| r.get::<_, i64>(0))?); } assert_eq!(1, cache.len()); cache.clear(); assert_eq!(0, cache.len()); assert_eq!(initial_capacity, cache.capacity()); Ok(()) } #[test] fn test_set_capacity() -> Result<()> { let db = Connection::open_in_memory()?; let cache = &db.cache; let sql = "PRAGMA schema_version"; { let mut stmt = db.prepare_cached(sql)?; assert_eq!(0, cache.len()); assert_eq!(0, stmt.query_row([], |r| r.get::<_, i64>(0))?); } assert_eq!(1, cache.len()); db.set_prepared_statement_cache_capacity(0); assert_eq!(0, cache.len()); { let mut stmt = db.prepare_cached(sql)?; assert_eq!(0, cache.len()); assert_eq!(0, stmt.query_row([], |r| r.get::<_, i64>(0))?); } assert_eq!(0, cache.len()); db.set_prepared_statement_cache_capacity(8); { let mut stmt = db.prepare_cached(sql)?; assert_eq!(0, cache.len()); assert_eq!(0, stmt.query_row([], |r| r.get::<_, i64>(0))?); } assert_eq!(1, cache.len()); Ok(()) } #[test] fn test_discard() -> Result<()> { let db = Connection::open_in_memory()?; let cache = &db.cache; let sql = "PRAGMA schema_version"; { let mut stmt = db.prepare_cached(sql)?; assert_eq!(0, cache.len()); assert_eq!(0, stmt.query_row([], |r| r.get::<_, i64>(0))?); stmt.discard(); } assert_eq!(0, cache.len()); Ok(()) } #[test] fn test_ddl() -> Result<()> { let db = Connection::open_in_memory()?; db.execute_batch( r#" CREATE TABLE foo (x INT); INSERT INTO foo VALUES (1); "#, )?; let sql = "SELECT * FROM foo"; { let mut stmt = db.prepare_cached(sql)?; assert_eq!(Ok(Some(1i32)), stmt.query([])?.map(|r| r.get(0)).next()); } db.execute_batch( r#" ALTER TABLE foo ADD COLUMN y INT; UPDATE foo SET y = 2; "#, )?; { let mut stmt = db.prepare_cached(sql)?; assert_eq!( Ok(Some((1i32, 2i32))), stmt.query([])?.map(|r| Ok((r.get(0)?, r.get(1)?))).next() ); } Ok(()) } #[test] fn test_connection_close() -> Result<()> { let conn = Connection::open_in_memory()?; conn.prepare_cached("SELECT * FROM sqlite_master;")?; conn.close().expect("connection not closed"); Ok(()) } #[test] fn test_cache_key() -> Result<()> { let db = Connection::open_in_memory()?; let cache = &db.cache; assert_eq!(0, cache.len()); //let sql = " PRAGMA schema_version; -- comment"; let sql = "PRAGMA schema_version; "; { let mut stmt = db.prepare_cached(sql)?; assert_eq!(0, cache.len()); assert_eq!(0, stmt.query_row([], |r| r.get::<_, i64>(0))?); } assert_eq!(1, cache.len()); { let mut stmt = db.prepare_cached(sql)?; assert_eq!(0, cache.len()); assert_eq!(0, stmt.query_row([], |r| r.get::<_, i64>(0))?); } assert_eq!(1, cache.len()); Ok(()) } #[test] fn test_empty_stmt() -> Result<()> { let conn = Connection::open_in_memory()?; conn.prepare_cached("")?; Ok(()) } }