rusqlite/src/unlock_notify.rs

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//! [Unlock Notification](http://sqlite.org/unlock_notify.html)
#[cfg(feature = "unlock_notify")]
use std::sync::{Condvar, Mutex};
use std::os::raw::c_int;
#[cfg(feature = "unlock_notify")]
use std::os::raw::c_void;
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use ffi;
#[cfg(feature = "unlock_notify")]
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struct UnlockNotification {
cond: Condvar, // Condition variable to wait on
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mutex: Mutex<bool>, // Mutex to protect structure
}
#[cfg(feature = "unlock_notify")]
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impl UnlockNotification {
fn new() -> UnlockNotification {
UnlockNotification {
cond: Condvar::new(),
mutex: Mutex::new(false),
}
}
fn fired(&mut self) {
*self.mutex.lock().unwrap() = true;
self.cond.notify_one();
}
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fn wait(&mut self) {
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let mut fired = self.mutex.lock().unwrap();
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while !*fired {
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fired = self.cond.wait(fired).unwrap();
}
}
}
/// This function is an unlock-notify callback
#[cfg(feature = "unlock_notify")]
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unsafe extern "C" fn unlock_notify_cb(ap_arg: *mut *mut c_void, n_arg: c_int) {
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use std::slice::from_raw_parts;
let args = from_raw_parts(ap_arg, n_arg as usize);
for arg in args {
let un: &mut UnlockNotification = &mut *(*arg as *mut UnlockNotification);
un.fired();
}
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}
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#[cfg(feature = "unlock_notify")]
pub fn is_locked(db: *mut ffi::sqlite3, rc: c_int) -> bool {
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rc == ffi::SQLITE_LOCKED_SHAREDCACHE || (rc & 0xFF) == ffi::SQLITE_LOCKED && unsafe {
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ffi::sqlite3_extended_errcode(db)
}
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== ffi::SQLITE_LOCKED_SHAREDCACHE
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}
/// This function assumes that an SQLite API call (either `sqlite3_prepare_v2()`
/// or `sqlite3_step()`) has just returned `SQLITE_LOCKED`. The argument is the
/// associated database connection.
///
/// This function calls `sqlite3_unlock_notify()` to register for an
/// unlock-notify callback, then blocks until that callback is delivered
/// and returns `SQLITE_OK`. The caller should then retry the failed operation.
///
/// Or, if `sqlite3_unlock_notify()` indicates that to block would deadlock
/// the system, then this function returns `SQLITE_LOCKED` immediately. In
/// this case the caller should not retry the operation and should roll
/// back the current transaction (if any).
#[cfg(feature = "unlock_notify")]
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pub fn wait_for_unlock_notify(db: *mut ffi::sqlite3) -> c_int {
let mut un = UnlockNotification::new();
/* Register for an unlock-notify callback. */
let rc = unsafe {
ffi::sqlite3_unlock_notify(
db,
Some(unlock_notify_cb),
&mut un as *mut UnlockNotification as *mut c_void,
)
};
debug_assert!(
rc == ffi::SQLITE_LOCKED || rc == ffi::SQLITE_LOCKED_SHAREDCACHE || rc == ffi::SQLITE_OK
);
if rc == ffi::SQLITE_OK {
un.wait();
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}
rc
}
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#[cfg(not(feature = "unlock_notify"))]
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pub fn is_locked(_db: *mut ffi::sqlite3, _rc: c_int) -> bool {
unreachable!()
}
#[cfg(not(feature = "unlock_notify"))]
pub fn wait_for_unlock_notify(_db: *mut ffi::sqlite3) -> c_int {
unreachable!()
}
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#[cfg(feature = "unlock_notify")]
#[cfg(test)]
mod test {
use std::sync::mpsc::sync_channel;
use std::thread;
use std::time;
use {Connection, OpenFlags, Result, Transaction, TransactionBehavior};
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#[test]
fn test_unlock_notify() {
let url = "file::memory:?cache=shared";
let flags = OpenFlags::SQLITE_OPEN_READ_WRITE | OpenFlags::SQLITE_OPEN_URI;
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let db1 = Connection::open_with_flags(url, flags).unwrap();
db1.execute_batch("CREATE TABLE foo (x)").unwrap();
let (rx, tx) = sync_channel(0);
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let child = thread::spawn(move || {
let mut db2 = Connection::open_with_flags(url, flags).unwrap();
let tx2 = Transaction::new(&mut db2, TransactionBehavior::Immediate).unwrap();
tx2.execute_batch("INSERT INTO foo VALUES (42)").unwrap();
rx.send(1).unwrap();
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let ten_millis = time::Duration::from_millis(10);
thread::sleep(ten_millis);
tx2.commit().unwrap();
});
assert_eq!(tx.recv().unwrap(), 1);
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let the_answer: Result<i64> = db1.query_row("SELECT x FROM foo", &[], |r| r.get(0));
assert_eq!(42i64, the_answer.unwrap());
child.join().unwrap();
}
}