use libc::{c_uint, size_t, mode_t}; use std::io::FilePermission; use std::ptr; use std::sync::Mutex; use ffi; use error::{LmdbResult, lmdb_result}; use database::Database; use transaction::{RoTransaction, RwTransaction, Transaction, TransactionExt}; use flags::{DatabaseFlags, EnvironmentFlags}; /// An LMDB environment. /// /// An environment supports multiple databases, all residing in the same shared-memory map. pub struct Environment { env: *mut ffi::MDB_env, dbi_open_mutex: Mutex<()>, } impl Environment { /// Creates a new builder for specifying options for opening an LMDB environment. pub fn new() -> EnvironmentBuilder { EnvironmentBuilder { flags: EnvironmentFlags::empty(), max_readers: None, max_dbs: None, map_size: None } } /// Returns a raw pointer to the underlying LMDB environment. /// /// The caller **must** ensure that the pointer is not dereferenced after the lifetime of the /// environment. pub fn env(&self) -> *mut ffi::MDB_env { self.env } /// Opens a handle to an LMDB database. /// /// If `name` is `None`, then the returned handle will be for the default database. /// /// If `name` is not `None`, then the returned handle will be for a named database. In this /// case the environment must be configured to allow named databases through /// `EnvironmentBuilder::set_max_dbs`. /// /// The returned database handle may be shared among any transaction in the environment. /// /// This function will fail with `LmdbError::BadRslot` if called by a thread which has an ongoing /// transaction. pub fn open_db<'env>(&'env self, name: Option<&str>) -> LmdbResult { let mutex = self.dbi_open_mutex.lock(); let txn = try!(self.begin_ro_txn()); let db = unsafe { try!(txn.open_db(name)) }; try!(txn.commit()); drop(mutex); Ok(db) } /// Opens a handle to an LMDB database, creating the database if necessary. /// /// If the database is already created, the given option flags will be added to it. /// /// If `name` is `None`, then the returned handle will be for the default database. /// /// If `name` is not `None`, then the returned handle will be for a named database. In this /// case the environment must be configured to allow named databases through /// `EnvironmentBuilder::set_max_dbs`. /// /// The returned database handle may be shared among any transaction in the environment. /// /// This function will fail with `LmdbError::BadRslot` if called by a thread with an open /// transaction. pub fn create_db<'env>(&'env self, name: Option<&str>, flags: DatabaseFlags) -> LmdbResult { let mutex = self.dbi_open_mutex.lock(); let txn = try!(self.begin_rw_txn()); let db = unsafe { try!(txn.create_db(name, flags)) }; try!(txn.commit()); drop(mutex); Ok(db) } pub fn get_db_flags<'env>(&'env self, db: Database) -> LmdbResult { let txn = try!(self.begin_ro_txn()); let mut flags: c_uint = 0; unsafe { try!(lmdb_result(ffi::mdb_dbi_flags(txn.txn(), db.dbi(), &mut flags))); } Ok(DatabaseFlags::from_bits(flags).unwrap()) } /// Create a read-only transaction for use with the environment. pub fn begin_ro_txn<'env>(&'env self) -> LmdbResult> { RoTransaction::new(self) } /// Create a read-write transaction for use with the environment. This method will block while /// there are any other read-write transactions open on the environment. pub fn begin_rw_txn<'env>(&'env self) -> LmdbResult> { RwTransaction::new(self) } /// Flush data buffers to disk. /// /// Data is always written to disk when `Transaction::commit` is called, but the operating /// system may keep it buffered. LMDB always flushes the OS buffers upon commit as well, unless /// the environment was opened with `MDB_NOSYNC` or in part `MDB_NOMETASYNC`. pub fn sync(&self, force: bool) -> LmdbResult<()> { unsafe { lmdb_result(ffi::mdb_env_sync(self.env(), if force { 1 } else { 0 })) } } /// Closes the database handle. Normally unnecessary. /// /// Closing a database handle is not necessary, but lets `Transaction::open_database` reuse the /// handle value. Usually it's better to set a bigger `EnvironmentBuilder::set_max_dbs`, unless /// that value would be large. /// /// ## Unsafety /// /// This call is not mutex protected. Databases should only be closed by a single thread, and /// only if no other threads are going to reference the database handle or one of its cursors /// any further. Do not close a handle if an existing transaction has modified its database. /// Doing so can cause misbehavior from database corruption to errors like /// `LmdbError::BadValSize` (since the DB name is gone). pub unsafe fn close_db(&mut self, db: Database) { ffi::mdb_dbi_close(self.env, db.dbi()); } } impl Drop for Environment { fn drop(&mut self) { unsafe { ffi::mdb_env_close(self.env) } } } /////////////////////////////////////////////////////////////////////////////////////////////////// //// Environment Builder /////////////////////////////////////////////////////////////////////////////////////////////////// /// Options for opening or creating an environment. #[deriving(Show, PartialEq, Eq, Copy, Clone)] pub struct EnvironmentBuilder { flags: EnvironmentFlags, max_readers: Option, max_dbs: Option, map_size: Option, } impl EnvironmentBuilder { /// Open an environment. pub fn open(&self, path: &Path, mode: FilePermission) -> LmdbResult { let mut env: *mut ffi::MDB_env = ptr::null_mut(); unsafe { lmdb_try!(ffi::mdb_env_create(&mut env)); if let Some(max_readers) = self.max_readers { lmdb_try_with_cleanup!(ffi::mdb_env_set_maxreaders(env, max_readers), ffi::mdb_env_close(env)) } if let Some(max_dbs) = self.max_dbs { lmdb_try_with_cleanup!(ffi::mdb_env_set_maxdbs(env, max_dbs), ffi::mdb_env_close(env)) } if let Some(map_size) = self.map_size { lmdb_try_with_cleanup!(ffi::mdb_env_set_mapsize(env, map_size), ffi::mdb_env_close(env)) } lmdb_try_with_cleanup!(ffi::mdb_env_open(env, path.to_c_str().as_ptr(), self.flags.bits(), mode.bits() as mode_t), ffi::mdb_env_close(env)); } Ok(Environment { env: env, dbi_open_mutex: Mutex::new(()) }) } pub fn set_flags(&mut self, flags: EnvironmentFlags) -> &mut EnvironmentBuilder { self.flags = flags; self } /// Sets the maximum number of threads or reader slots for the environment. /// /// This defines the number of slots in the lock table that is used to track readers in the /// the environment. The default is 126. Starting a read-only transaction normally ties a lock /// table slot to the current thread until the environment closes or the thread exits. If /// `MDB_NOTLS` is in use, `Environment::open_txn` instead ties the slot to the `Transaction` /// object until it or the `Environment` object is destroyed. pub fn set_max_readers(&mut self, max_readers: c_uint) -> &mut EnvironmentBuilder { self.max_readers = Some(max_readers); self } /// Sets the maximum number of named databases for the environment. /// /// This function is only needed if multiple databases will be used in the /// environment. Simpler applications that use the environment as a single /// unnamed database can ignore this option. /// /// Currently a moderate number of slots are cheap but a huge number gets /// expensive: 7-120 words per transaction, and every `Transaction::open_db` /// does a linear search of the opened slots. pub fn set_max_dbs(&mut self, max_readers: c_uint) -> &mut EnvironmentBuilder { self.max_dbs = Some(max_readers); self } /// Sets the size of the memory map to use for the environment. /// /// The size should be a multiple of the OS page size. The default is /// 10485760 bytes. The size of the memory map is also the maximum size /// of the database. The value should be chosen as large as possible, /// to accommodate future growth of the database. It may be increased at /// later times. /// /// Any attempt to set a size smaller than the space already consumed /// by the environment will be silently changed to the current size of the used space. pub fn set_map_size(&mut self, map_size: size_t) -> &mut EnvironmentBuilder { self.map_size = Some(map_size); self } } #[cfg(test)] mod test { use std::io; use flags::*; use super::*; #[test] fn test_open() { let dir = io::TempDir::new("test").unwrap(); // opening non-existent env with read-only should fail assert!(Environment::new().set_flags(READ_ONLY) .open(dir.path(), io::USER_RWX) .is_err()); // opening non-existent env should succeed assert!(Environment::new().open(dir.path(), io::USER_RWX).is_ok()); // opening env with read-only should succeed assert!(Environment::new().set_flags(READ_ONLY) .open(dir.path(), io::USER_RWX) .is_ok()); } #[test] fn test_begin_txn() { let dir = io::TempDir::new("test").unwrap(); { // writable environment let env = Environment::new().open(dir.path(), io::USER_RWX).unwrap(); assert!(env.begin_rw_txn().is_ok()); assert!(env.begin_ro_txn().is_ok()); } { // read-only environment let env = Environment::new().set_flags(READ_ONLY) .open(dir.path(), io::USER_RWX) .unwrap(); assert!(env.begin_rw_txn().is_err()); assert!(env.begin_ro_txn().is_ok()); } } #[test] fn test_open_db() { let dir = io::TempDir::new("test").unwrap(); let env = Environment::new().set_max_dbs(1) .open(dir.path(), io::USER_RWX) .unwrap(); assert!(env.open_db(None).is_ok()); assert!(env.open_db(Some("testdb")).is_err()); } #[test] fn test_create_db() { let dir = io::TempDir::new("test").unwrap(); let env = Environment::new().set_max_dbs(11) .open(dir.path(), io::USER_RWX) .unwrap(); assert!(env.open_db(Some("testdb")).is_err()); assert!(env.create_db(Some("testdb"), DatabaseFlags::empty()).is_ok()); assert!(env.open_db(Some("testdb")).is_ok()) } #[test] fn test_close_database() { let dir = io::TempDir::new("test").unwrap(); let mut env = Environment::new().set_max_dbs(10) .open(dir.path(), io::USER_RWX) .unwrap(); let db = env.create_db(Some("db"), DatabaseFlags::empty()).unwrap(); unsafe { env.close_db(db); } assert!(env.open_db(Some("db")).is_ok()); } #[test] fn test_sync() { let dir = io::TempDir::new("test").unwrap(); { let env = Environment::new().open(dir.path(), io::USER_RWX).unwrap(); assert!(env.sync(true).is_ok()); } { let env = Environment::new().set_flags(READ_ONLY) .open(dir.path(), io::USER_RWX) .unwrap(); assert!(env.sync(true).is_ok()); } } }