src/librustc_data_structures/sync.rs - third_party/rust - Git at Google

 //! This module defines types which are thread safe if cfg!(parallel_compiler) is true.
 //!
 //! `Lrc` is an alias of either Rc or Arc.
 //!
 //! `Lock` is a mutex.
 //! It internally uses `parking_lot::Mutex` if cfg!(parallel_compiler) is true,
 //! `RefCell` otherwise.
 //!
 //! `RwLock` is a read-write lock.
 //! It internally uses `parking_lot::RwLock` if cfg!(parallel_compiler) is true,
 //! `RefCell` otherwise.
 //!
 //! `MTLock` is a mutex which disappears if cfg!(parallel_compiler) is false.
 //!
 //! `MTRef` is a immutable reference if cfg!(parallel_compiler), and an mutable reference otherwise.
 //!
 //! `rustc_erase_owner!` erases a OwningRef owner into Erased or Erased + Send + Sync
 //! depending on the value of cfg!(parallel_compiler).

 use std::collections::HashMap;
 use std::hash::{Hash, BuildHasher};
 use std::marker::PhantomData;
 use std::ops::{Deref, DerefMut};
 use crate::owning_ref::{Erased, OwningRef};

 pub fn serial_join<A, B, RA, RB>(oper_a: A, oper_b: B) -> (RA, RB)
     where A: FnOnce() -> RA,
           B: FnOnce() -> RB
 {
     (oper_a(), oper_b())
 }

 pub struct SerialScope;

 impl SerialScope {
     pub fn spawn<F>(&self, f: F)
         where F: FnOnce(&SerialScope)
     {
         f(self)
     }
 }

 pub fn serial_scope<F, R>(f: F) -> R
     where F: FnOnce(&SerialScope) -> R
 {
     f(&SerialScope)
 }

 pub use std::sync::atomic::Ordering::SeqCst;
 pub use std::sync::atomic::Ordering;

 cfg_if! {
     if #[cfg(not(parallel_compiler))] {
         pub auto trait Send {}
         pub auto trait Sync {}

         impl<T: ?Sized> Send for T {}
         impl<T: ?Sized> Sync for T {}

         #[macro_export]
         macro_rules! rustc_erase_owner {
             ($v:expr) => {
                 $v.erase_owner()
             }
         }

         use std::ops::Add;
         use std::panic::{resume_unwind, catch_unwind, AssertUnwindSafe};

         /// This is a single threaded variant of AtomicCell provided by crossbeam.
         /// Unlike `Atomic` this is intended for all `Copy` types,
         /// but it lacks the explicit ordering arguments.
         #[derive(Debug)]
         pub struct AtomicCell<T: Copy>(Cell<T>);

         impl<T: Copy> AtomicCell<T> {
             #[inline]
             pub fn new(v: T) -> Self {
                 AtomicCell(Cell::new(v))
             }

             #[inline]
             pub fn get_mut(&mut self) -> &mut T {
                 self.0.get_mut()
             }
         }

         impl<T: Copy> AtomicCell<T> {
             #[inline]
             pub fn into_inner(self) -> T {
                 self.0.into_inner()
             }

             #[inline]
             pub fn load(&self) -> T {
                 self.0.get()
             }

             #[inline]
             pub fn store(&self, val: T) {
                 self.0.set(val)
             }

             #[inline]
             pub fn swap(&self, val: T) -> T {
                 self.0.replace(val)
             }
         }

         /// This is a single threaded variant of `AtomicU64`, `AtomicUsize`, etc.
         /// It differs from `AtomicCell` in that it has explicit ordering arguments
         /// and is only intended for use with the native atomic types.
         /// You should use this type through the `AtomicU64`, `AtomicUsize`, etc, type aliases
         /// as it's not intended to be used separately.
         #[derive(Debug)]
         pub struct Atomic<T: Copy>(Cell<T>);

         impl<T: Copy> Atomic<T> {
             #[inline]
             pub fn new(v: T) -> Self {
                 Atomic(Cell::new(v))
             }
         }

         impl<T: Copy> Atomic<T> {
             #[inline]
             pub fn into_inner(self) -> T {
                 self.0.into_inner()
             }

             #[inline]
             pub fn load(&self, _: Ordering) -> T {
                 self.0.get()
             }

             #[inline]
             pub fn store(&self, val: T, _: Ordering) {
                 self.0.set(val)
             }

             #[inline]
             pub fn swap(&self, val: T, _: Ordering) -> T {
                 self.0.replace(val)
             }
         }

         impl<T: Copy + PartialEq> Atomic<T> {
             #[inline]
             pub fn compare_exchange(&self,
                                     current: T,
                                     new: T,
                                     _: Ordering,
                                     _: Ordering)
                                     -> Result<T, T> {
                 let read = self.0.get();
                 if read == current {
                     self.0.set(new);
                     Ok(read)
                 } else {
                     Err(read)
                 }
             }
         }

         impl<T: Add<Output=T> + Copy> Atomic<T> {
             #[inline]
             pub fn fetch_add(&self, val: T, _: Ordering) -> T {
                 let old = self.0.get();
                 self.0.set(old + val);
                 old
             }
         }

         pub type AtomicUsize = Atomic<usize>;
         pub type AtomicBool = Atomic<bool>;
         pub type AtomicU32 = Atomic<u32>;
         pub type AtomicU64 = Atomic<u64>;

         pub use self::serial_join as join;
         pub use self::serial_scope as scope;

         #[macro_export]
         macro_rules! parallel {
             ($($blocks:tt),*) => {
                 // We catch panics here ensuring that all the blocks execute.
                 // This makes behavior consistent with the parallel compiler.
                 let mut panic = None;
                 $(
                     if let Err(p) = ::std::panic::catch_unwind(
                         ::std::panic::AssertUnwindSafe(|| $blocks)
                     ) {
                         if panic.is_none() {
                             panic = Some(p);
                         }
                     }
                 )*
                 if let Some(panic) = panic {
                     ::std::panic::resume_unwind(panic);
                 }
             }
         }

         pub use std::iter::Iterator as ParallelIterator;

         pub fn par_iter<T: IntoIterator>(t: T) -> T::IntoIter {
             t.into_iter()
         }

         pub fn par_for_each_in<T: IntoIterator>(
             t: T,
             for_each:
                 impl Fn(<<T as IntoIterator>::IntoIter as Iterator>::Item) + Sync + Send
         ) {
             // We catch panics here ensuring that all the loop iterations execute.
             // This makes behavior consistent with the parallel compiler.
             let mut panic = None;
             t.into_iter().for_each(|i| {
                 if let Err(p) = catch_unwind(AssertUnwindSafe(|| for_each(i))) {
                     if panic.is_none() {
                         panic = Some(p);
                     }
                 }
             });
             if let Some(panic) = panic {
                 resume_unwind(panic);
             }
         }

         pub type MetadataRef = OwningRef<Box<dyn Erased>, [u8]>;

         pub use std::rc::Rc as Lrc;
         pub use std::rc::Weak as Weak;
         pub use std::cell::Ref as ReadGuard;
         pub use std::cell::Ref as MappedReadGuard;
         pub use std::cell::RefMut as WriteGuard;
         pub use std::cell::RefMut as MappedWriteGuard;
         pub use std::cell::RefMut as LockGuard;
         pub use std::cell::RefMut as MappedLockGuard;

         use std::cell::RefCell as InnerRwLock;
         use std::cell::RefCell as InnerLock;

         use std::cell::Cell;

         #[derive(Debug)]
         pub struct WorkerLocal<T>(OneThread<T>);

         impl<T> WorkerLocal<T> {
             /// Creates a new worker local where the `initial` closure computes the
             /// value this worker local should take for each thread in the thread pool.
             #[inline]
             pub fn new<F: FnMut(usize) -> T>(mut f: F) -> WorkerLocal<T> {
                 WorkerLocal(OneThread::new(f(0)))
             }

             /// Returns the worker-local value for each thread
             #[inline]
             pub fn into_inner(self) -> Vec<T> {
                 vec![OneThread::into_inner(self.0)]
             }
         }

         impl<T> Deref for WorkerLocal<T> {
             type Target = T;

             #[inline(always)]
             fn deref(&self) -> &T {
                 &*self.0
             }
         }

         pub type MTRef<'a, T> = &'a mut T;

         #[derive(Debug, Default)]
         pub struct MTLock<T>(T);

         impl<T> MTLock<T> {
             #[inline(always)]
             pub fn new(inner: T) -> Self {
                 MTLock(inner)
             }

             #[inline(always)]
             pub fn into_inner(self) -> T {
                 self.0
             }

             #[inline(always)]
             pub fn get_mut(&mut self) -> &mut T {
                 &mut self.0
             }

             #[inline(always)]
             pub fn lock(&self) -> &T {
                 &self.0
             }

             #[inline(always)]
             pub fn lock_mut(&mut self) -> &mut T {
                 &mut self.0
             }
         }

         // FIXME: Probably a bad idea (in the threaded case)
         impl<T: Clone> Clone for MTLock<T> {
             #[inline]
             fn clone(&self) -> Self {
                 MTLock(self.0.clone())
             }
         }
     } else {
         pub use std::marker::Send as Send;
         pub use std::marker::Sync as Sync;

         pub use parking_lot::RwLockReadGuard as ReadGuard;
         pub use parking_lot::MappedRwLockReadGuard as MappedReadGuard;
         pub use parking_lot::RwLockWriteGuard as WriteGuard;
         pub use parking_lot::MappedRwLockWriteGuard as MappedWriteGuard;

         pub use parking_lot::MutexGuard as LockGuard;
         pub use parking_lot::MappedMutexGuard as MappedLockGuard;

         pub use std::sync::atomic::{AtomicBool, AtomicUsize, AtomicU32, AtomicU64};

         pub use crossbeam_utils::atomic::AtomicCell;

         pub use std::sync::Arc as Lrc;
         pub use std::sync::Weak as Weak;

         pub type MTRef<'a, T> = &'a T;

         #[derive(Debug, Default)]
         pub struct MTLock<T>(Lock<T>);

         impl<T> MTLock<T> {
             #[inline(always)]
             pub fn new(inner: T) -> Self {
                 MTLock(Lock::new(inner))
             }

             #[inline(always)]
             pub fn into_inner(self) -> T {
                 self.0.into_inner()
             }

             #[inline(always)]
             pub fn get_mut(&mut self) -> &mut T {
                 self.0.get_mut()
             }

             #[inline(always)]
             pub fn lock(&self) -> LockGuard<'_, T> {
                 self.0.lock()
             }

             #[inline(always)]
             pub fn lock_mut(&self) -> LockGuard<'_, T> {
                 self.lock()
             }
         }

         use parking_lot::Mutex as InnerLock;
         use parking_lot::RwLock as InnerRwLock;

         use std;
         use std::thread;
         pub use rayon::{join, scope};

         /// Runs a list of blocks in parallel. The first block is executed immediately on
         /// the current thread. Use that for the longest running block.
         #[macro_export]
         macro_rules! parallel {
             (impl $fblock:tt [$($c:tt,)*] [$block:tt $(, $rest:tt)*]) => {
                 parallel!(impl $fblock [$block, $($c,)*] [$($rest),*])
             };
             (impl $fblock:tt [$($blocks:tt,)*] []) => {
                 ::rustc_data_structures::sync::scope(|s| {
                     $(
                         s.spawn(|_| $blocks);
                     )*
                     $fblock;
                 })
             };
             ($fblock:tt, $($blocks:tt),*) => {
                 // Reverse the order of the later blocks since Rayon executes them in reverse order
                 // when using a single thread. This ensures the execution order matches that
                 // of a single threaded rustc
                 parallel!(impl $fblock [] [$($blocks),*]);
             };
         }

         pub use rayon_core::WorkerLocal;

         pub use rayon::iter::ParallelIterator;
         use rayon::iter::IntoParallelIterator;

         pub fn par_iter<T: IntoParallelIterator>(t: T) -> T::Iter {
             t.into_par_iter()
         }

         pub fn par_for_each_in<T: IntoParallelIterator>(
             t: T,
             for_each: impl Fn(
                 <<T as IntoParallelIterator>::Iter as ParallelIterator>::Item
             ) + Sync + Send
         ) {
             t.into_par_iter().for_each(for_each)
         }

         pub type MetadataRef = OwningRef<Box<dyn Erased + Send + Sync>, [u8]>;

         /// This makes locks panic if they are already held.
         /// It is only useful when you are running in a single thread
         const ERROR_CHECKING: bool = false;

         #[macro_export]
         macro_rules! rustc_erase_owner {
             ($v:expr) => {{
                 let v = $v;
                 ::rustc_data_structures::sync::assert_send_val(&v);
                 v.erase_send_sync_owner()
             }}
         }
     }
 }

 pub fn assert_sync<T: ?Sized + Sync>() {}
 pub fn assert_send<T: ?Sized + Send>() {}
 pub fn assert_send_val<T: ?Sized + Send>(_t: &T) {}
 pub fn assert_send_sync_val<T: ?Sized + Sync + Send>(_t: &T) {}

 pub trait HashMapExt<K, V> {
     /// Same as HashMap::insert, but it may panic if there's already an
     /// entry for `key` with a value not equal to `value`
     fn insert_same(&mut self, key: K, value: V);
 }

 impl<K: Eq + Hash, V: Eq, S: BuildHasher> HashMapExt<K, V> for HashMap<K, V, S> {
     fn insert_same(&mut self, key: K, value: V) {
         self.entry(key).and_modify(|old| assert!(*old == value)).or_insert(value);
     }
 }

 /// A type whose inner value can be written once and then will stay read-only
 // This contains a PhantomData<T> since this type conceptually owns a T outside the Mutex once
 // initialized. This ensures that Once<T> is Sync only if T is. If we did not have PhantomData<T>
 // we could send a &Once<Cell<bool>> to multiple threads and call `get` on it to get access
 // to &Cell<bool> on those threads.
 pub struct Once<T>(Lock<Option<T>>, PhantomData<T>);

 impl<T> Once<T> {
     /// Creates an Once value which is uninitialized
     #[inline(always)]
     pub fn new() -> Self {
         Once(Lock::new(None), PhantomData)
     }

     /// Consumes the value and returns Some(T) if it was initialized
     #[inline(always)]
     pub fn into_inner(self) -> Option<T> {
         self.0.into_inner()
     }

     /// Tries to initialize the inner value to `value`.
     /// Returns `None` if the inner value was uninitialized and `value` was consumed setting it
     /// otherwise if the inner value was already set it returns `value` back to the caller
     #[inline]
     pub fn try_set(&self, value: T) -> Option<T> {
         let mut lock = self.0.lock();
         if lock.is_some() {
             return Some(value);
         }
         *lock = Some(value);
         None
     }

     /// Tries to initialize the inner value to `value`.
     /// Returns `None` if the inner value was uninitialized and `value` was consumed setting it
     /// otherwise if the inner value was already set it asserts that `value` is equal to the inner
     /// value and then returns `value` back to the caller
     #[inline]
     pub fn try_set_same(&self, value: T) -> Option<T> where T: Eq {
         let mut lock = self.0.lock();
         if let Some(ref inner) = *lock {
             assert!(*inner == value);
             return Some(value);
         }
         *lock = Some(value);
         None
     }

     /// Tries to initialize the inner value to `value` and panics if it was already initialized
     #[inline]
     pub fn set(&self, value: T) {
         assert!(self.try_set(value).is_none());
     }

     /// Tries to initialize the inner value by calling the closure while ensuring that no-one else
     /// can access the value in the mean time by holding a lock for the duration of the closure.
     /// If the value was already initialized the closure is not called and `false` is returned,
     /// otherwise if the value from the closure initializes the inner value, `true` is returned
     #[inline]
     pub fn init_locking<F: FnOnce() -> T>(&self, f: F) -> bool {
         let mut lock = self.0.lock();
         if lock.is_some() {
             return false;
         }
         *lock = Some(f());
         true
     }

     /// Tries to initialize the inner value by calling the closure without ensuring that no-one
     /// else can access it. This mean when this is called from multiple threads, multiple
     /// closures may concurrently be computing a value which the inner value should take.
     /// Only one of these closures are used to actually initialize the value.
     /// If some other closure already set the value,
     /// we return the value our closure computed wrapped in a `Option`.
     /// If our closure set the value, `None` is returned.
     /// If the value is already initialized, the closure is not called and `None` is returned.
     #[inline]
     pub fn init_nonlocking<F: FnOnce() -> T>(&self, f: F) -> Option<T> {
         if self.0.lock().is_some() {
             None
         } else {
             self.try_set(f())
         }
     }

     /// Tries to initialize the inner value by calling the closure without ensuring that no-one
     /// else can access it. This mean when this is called from multiple threads, multiple
     /// closures may concurrently be computing a value which the inner value should take.
     /// Only one of these closures are used to actually initialize the value.
     /// If some other closure already set the value, we assert that it our closure computed
     /// a value equal to the value already set and then
     /// we return the value our closure computed wrapped in a `Option`.
     /// If our closure set the value, `None` is returned.
     /// If the value is already initialized, the closure is not called and `None` is returned.
     #[inline]
     pub fn init_nonlocking_same<F: FnOnce() -> T>(&self, f: F) -> Option<T> where T: Eq {
         if self.0.lock().is_some() {
             None
         } else {
             self.try_set_same(f())
         }
     }

     /// Tries to get a reference to the inner value, returns `None` if it is not yet initialized
     #[inline(always)]
     pub fn try_get(&self) -> Option<&T> {
         let lock = &*self.0.lock();
         if let Some(ref inner) = *lock {
             // This is safe since we won't mutate the inner value
             unsafe { Some(&*(inner as *const T)) }
         } else {
             None
         }
     }

     /// Gets reference to the inner value, panics if it is not yet initialized
     #[inline(always)]
     pub fn get(&self) -> &T {
         self.try_get().expect("value was not set")
     }

     /// Gets reference to the inner value, panics if it is not yet initialized
     #[inline(always)]
     pub fn borrow(&self) -> &T {
         self.get()
     }
 }

 #[derive(Debug)]
 pub struct Lock<T>(InnerLock<T>);

 impl<T> Lock<T> {
     #[inline(always)]
     pub fn new(inner: T) -> Self {
         Lock(InnerLock::new(inner))
     }

     #[inline(always)]
     pub fn into_inner(self) -> T {
         self.0.into_inner()
     }

     #[inline(always)]
     pub fn get_mut(&mut self) -> &mut T {
         self.0.get_mut()
     }

     #[cfg(parallel_compiler)]
     #[inline(always)]
     pub fn try_lock(&self) -> Option<LockGuard<'_, T>> {
         self.0.try_lock()
     }

     #[cfg(not(parallel_compiler))]
     #[inline(always)]
     pub fn try_lock(&self) -> Option<LockGuard<'_, T>> {
         self.0.try_borrow_mut().ok()
     }

     #[cfg(parallel_compiler)]
     #[inline(always)]
     pub fn lock(&self) -> LockGuard<'_, T> {
         if ERROR_CHECKING {
             self.0.try_lock().expect("lock was already held")
         } else {
             self.0.lock()
         }
     }

     #[cfg(not(parallel_compiler))]
     #[inline(always)]
     pub fn lock(&self) -> LockGuard<'_, T> {
         self.0.borrow_mut()
     }

     #[inline(always)]
     pub fn with_lock<F: FnOnce(&mut T) -> R, R>(&self, f: F) -> R {
         f(&mut *self.lock())
     }

     #[inline(always)]
     pub fn borrow(&self) -> LockGuard<'_, T> {
         self.lock()
     }

     #[inline(always)]
     pub fn borrow_mut(&self) -> LockGuard<'_, T> {
         self.lock()
     }
 }

 impl<T: Default> Default for Lock<T> {
     #[inline]
     fn default() -> Self {
         Lock::new(T::default())
     }
 }

 // FIXME: Probably a bad idea
 impl<T: Clone> Clone for Lock<T> {
     #[inline]
     fn clone(&self) -> Self {
         Lock::new(self.borrow().clone())
     }
 }

 #[derive(Debug)]
 pub struct RwLock<T>(InnerRwLock<T>);

 impl<T> RwLock<T> {
     #[inline(always)]
     pub fn new(inner: T) -> Self {
         RwLock(InnerRwLock::new(inner))
     }

     #[inline(always)]
     pub fn into_inner(self) -> T {
         self.0.into_inner()
     }

     #[inline(always)]
     pub fn get_mut(&mut self) -> &mut T {
         self.0.get_mut()
     }

     #[cfg(not(parallel_compiler))]
     #[inline(always)]
     pub fn read(&self) -> ReadGuard<'_, T> {
         self.0.borrow()
     }

     #[cfg(parallel_compiler)]
     #[inline(always)]
     pub fn read(&self) -> ReadGuard<'_, T> {
         if ERROR_CHECKING {
             self.0.try_read().expect("lock was already held")
         } else {
             self.0.read()
         }
     }

     #[inline(always)]
     pub fn with_read_lock<F: FnOnce(&T) -> R, R>(&self, f: F) -> R {
         f(&*self.read())
     }

     #[cfg(not(parallel_compiler))]
     #[inline(always)]
     pub fn try_write(&self) -> Result<WriteGuard<'_, T>, ()> {
         self.0.try_borrow_mut().map_err(|_| ())
     }

     #[cfg(parallel_compiler)]
     #[inline(always)]
     pub fn try_write(&self) -> Result<WriteGuard<'_, T>, ()> {
         self.0.try_write().ok_or(())
     }

     #[cfg(not(parallel_compiler))]
     #[inline(always)]
     pub fn write(&self) -> WriteGuard<'_, T> {
         self.0.borrow_mut()
     }

     #[cfg(parallel_compiler)]
     #[inline(always)]
     pub fn write(&self) -> WriteGuard<'_, T> {
         if ERROR_CHECKING {
             self.0.try_write().expect("lock was already held")
         } else {
             self.0.write()
         }
     }

     #[inline(always)]
     pub fn with_write_lock<F: FnOnce(&mut T) -> R, R>(&self, f: F) -> R {
         f(&mut *self.write())
     }

     #[inline(always)]
     pub fn borrow(&self) -> ReadGuard<'_, T> {
         self.read()
     }

     #[inline(always)]
     pub fn borrow_mut(&self) -> WriteGuard<'_, T> {
         self.write()
     }
 }

 // FIXME: Probably a bad idea
 impl<T: Clone> Clone for RwLock<T> {
     #[inline]
     fn clone(&self) -> Self {
         RwLock::new(self.borrow().clone())
     }
 }

 /// A type which only allows its inner value to be used in one thread.
 /// It will panic if it is used on multiple threads.
 #[derive(Copy, Clone, Hash, Debug, Eq, PartialEq)]
 pub struct OneThread<T> {
     #[cfg(parallel_compiler)]
     thread: thread::ThreadId,
     inner: T,
 }

 #[cfg(parallel_compiler)]
 unsafe impl<T> std::marker::Sync for OneThread<T> {}
 #[cfg(parallel_compiler)]
 unsafe impl<T> std::marker::Send for OneThread<T> {}

 impl<T> OneThread<T> {
     #[inline(always)]
     fn check(&self) {
         #[cfg(parallel_compiler)]
         assert_eq!(thread::current().id(), self.thread);
     }

     #[inline(always)]
     pub fn new(inner: T) -> Self {
         OneThread {
             #[cfg(parallel_compiler)]
             thread: thread::current().id(),
             inner,
         }
     }

     #[inline(always)]
     pub fn into_inner(value: Self) -> T {
         value.check();
         value.inner
     }
 }

 impl<T> Deref for OneThread<T> {
     type Target = T;

     fn deref(&self) -> &T {
         self.check();
         &self.inner
     }
 }

 impl<T> DerefMut for OneThread<T> {
     fn deref_mut(&mut self) -> &mut T {
         self.check();
         &mut self.inner
     }
 }
	//! This module defines types which are thread safe if cfg!(parallel_compiler) is true.
	//!
	//! `Lrc` is an alias of either Rc or Arc.
	//!
	//! `Lock` is a mutex.
	//! It internally uses `parking_lot::Mutex` if cfg!(parallel_compiler) is true,
	//! `RefCell` otherwise.
	//!
	//! `RwLock` is a read-write lock.
	//! It internally uses `parking_lot::RwLock` if cfg!(parallel_compiler) is true,
	//! `RefCell` otherwise.
	//!
	//! `MTLock` is a mutex which disappears if cfg!(parallel_compiler) is false.
	//!
	//! `MTRef` is a immutable reference if cfg!(parallel_compiler), and an mutable reference otherwise.
	//!
	//! `rustc_erase_owner!` erases a OwningRef owner into Erased or Erased + Send + Sync
	//! depending on the value of cfg!(parallel_compiler).

	use std::collections::HashMap;
	use std::hash::{Hash, BuildHasher};
	use std::marker::PhantomData;
	use std::ops::{Deref, DerefMut};
	use crate::owning_ref::{Erased, OwningRef};

	pub fn serial_join<A, B, RA, RB>(oper_a: A, oper_b: B) -> (RA, RB)
	where A: FnOnce() -> RA,
	B: FnOnce() -> RB
	{
	(oper_a(), oper_b())
	}

	pub struct SerialScope;

	impl SerialScope {
	pub fn spawn<F>(&self, f: F)
	where F: FnOnce(&SerialScope)
	{
	f(self)
	}
	}

	pub fn serial_scope<F, R>(f: F) -> R
	where F: FnOnce(&SerialScope) -> R
	{
	f(&SerialScope)
	}

	pub use std::sync::atomic::Ordering::SeqCst;
	pub use std::sync::atomic::Ordering;

	cfg_if! {
	if #[cfg(not(parallel_compiler))] {
	pub auto trait Send {}
	pub auto trait Sync {}

	impl<T: ?Sized> Send for T {}
	impl<T: ?Sized> Sync for T {}

	#[macro_export]
	macro_rules! rustc_erase_owner {
	($v:expr) => {
	$v.erase_owner()
	}
	}

	use std::ops::Add;
	use std::panic::{resume_unwind, catch_unwind, AssertUnwindSafe};

	/// This is a single threaded variant of AtomicCell provided by crossbeam.
	/// Unlike `Atomic` this is intended for all `Copy` types,
	/// but it lacks the explicit ordering arguments.
	#[derive(Debug)]
	pub struct AtomicCell<T: Copy>(Cell<T>);

	impl<T: Copy> AtomicCell<T> {
	#[inline]
	pub fn new(v: T) -> Self {
	AtomicCell(Cell::new(v))
	}

	#[inline]
	pub fn get_mut(&mut self) -> &mut T {
	self.0.get_mut()
	}
	}

	impl<T: Copy> AtomicCell<T> {
	#[inline]
	pub fn into_inner(self) -> T {
	self.0.into_inner()
	}

	#[inline]
	pub fn load(&self) -> T {
	self.0.get()
	}

	#[inline]
	pub fn store(&self, val: T) {
	self.0.set(val)
	}

	#[inline]
	pub fn swap(&self, val: T) -> T {
	self.0.replace(val)
	}
	}

	/// This is a single threaded variant of `AtomicU64`, `AtomicUsize`, etc.
	/// It differs from `AtomicCell` in that it has explicit ordering arguments
	/// and is only intended for use with the native atomic types.
	/// You should use this type through the `AtomicU64`, `AtomicUsize`, etc, type aliases
	/// as it's not intended to be used separately.
	#[derive(Debug)]
	pub struct Atomic<T: Copy>(Cell<T>);

	impl<T: Copy> Atomic<T> {
	#[inline]
	pub fn new(v: T) -> Self {
	Atomic(Cell::new(v))
	}
	}

	impl<T: Copy> Atomic<T> {
	#[inline]
	pub fn into_inner(self) -> T {
	self.0.into_inner()
	}

	#[inline]
	pub fn load(&self, _: Ordering) -> T {
	self.0.get()
	}

	#[inline]
	pub fn store(&self, val: T, _: Ordering) {
	self.0.set(val)
	}

	#[inline]
	pub fn swap(&self, val: T, _: Ordering) -> T {
	self.0.replace(val)
	}
	}

	impl<T: Copy + PartialEq> Atomic<T> {
	#[inline]
	pub fn compare_exchange(&self,
	current: T,
	new: T,
	_: Ordering,
	_: Ordering)
	-> Result<T, T> {
	let read = self.0.get();
	if read == current {
	self.0.set(new);
	Ok(read)
	} else {
	Err(read)
	}
	}
	}

	impl<T: Add<Output=T> + Copy> Atomic<T> {
	#[inline]
	pub fn fetch_add(&self, val: T, _: Ordering) -> T {
	let old = self.0.get();
	self.0.set(old + val);
	old
	}
	}

	pub type AtomicUsize = Atomic<usize>;
	pub type AtomicBool = Atomic<bool>;
	pub type AtomicU32 = Atomic<u32>;
	pub type AtomicU64 = Atomic<u64>;

	pub use self::serial_join as join;
	pub use self::serial_scope as scope;

	#[macro_export]
	macro_rules! parallel {
	($($blocks:tt),*) => {
	// We catch panics here ensuring that all the blocks execute.
	// This makes behavior consistent with the parallel compiler.
	let mut panic = None;
	$(
	if let Err(p) = ::std::panic::catch_unwind(
	::std::panic::AssertUnwindSafe(\|\| $blocks)
	) {
	if panic.is_none() {
	panic = Some(p);
	}
	}
	)*
	if let Some(panic) = panic {
	::std::panic::resume_unwind(panic);
	}
	}
	}

	pub use std::iter::Iterator as ParallelIterator;

	pub fn par_iter<T: IntoIterator>(t: T) -> T::IntoIter {
	t.into_iter()
	}

	pub fn par_for_each_in<T: IntoIterator>(
	t: T,
	for_each:
	impl Fn(<<T as IntoIterator>::IntoIter as Iterator>::Item) + Sync + Send
	) {
	// We catch panics here ensuring that all the loop iterations execute.
	// This makes behavior consistent with the parallel compiler.
	let mut panic = None;
	t.into_iter().for_each(\|i\| {
	if let Err(p) = catch_unwind(AssertUnwindSafe(\|\| for_each(i))) {
	if panic.is_none() {
	panic = Some(p);
	}
	}
	});
	if let Some(panic) = panic {
	resume_unwind(panic);
	}
	}

	pub type MetadataRef = OwningRef<Box<dyn Erased>, [u8]>;

	pub use std::rc::Rc as Lrc;
	pub use std::rc::Weak as Weak;
	pub use std::cell::Ref as ReadGuard;
	pub use std::cell::Ref as MappedReadGuard;
	pub use std::cell::RefMut as WriteGuard;
	pub use std::cell::RefMut as MappedWriteGuard;
	pub use std::cell::RefMut as LockGuard;
	pub use std::cell::RefMut as MappedLockGuard;

	use std::cell::RefCell as InnerRwLock;
	use std::cell::RefCell as InnerLock;

	use std::cell::Cell;

	#[derive(Debug)]
	pub struct WorkerLocal<T>(OneThread<T>);

	impl<T> WorkerLocal<T> {
	/// Creates a new worker local where the `initial` closure computes the
	/// value this worker local should take for each thread in the thread pool.
	#[inline]
	pub fn new<F: FnMut(usize) -> T>(mut f: F) -> WorkerLocal<T> {
	WorkerLocal(OneThread::new(f(0)))
	}

	/// Returns the worker-local value for each thread
	#[inline]
	pub fn into_inner(self) -> Vec<T> {
	vec![OneThread::into_inner(self.0)]
	}
	}

	impl<T> Deref for WorkerLocal<T> {
	type Target = T;

	#[inline(always)]
	fn deref(&self) -> &T {
	&*self.0
	}
	}

	pub type MTRef<'a, T> = &'a mut T;

	#[derive(Debug, Default)]
	pub struct MTLock<T>(T);

	impl<T> MTLock<T> {
	#[inline(always)]
	pub fn new(inner: T) -> Self {
	MTLock(inner)
	}

	#[inline(always)]
	pub fn into_inner(self) -> T {
	self.0
	}

	#[inline(always)]
	pub fn get_mut(&mut self) -> &mut T {
	&mut self.0
	}

	#[inline(always)]
	pub fn lock(&self) -> &T {
	&self.0
	}

	#[inline(always)]
	pub fn lock_mut(&mut self) -> &mut T {
	&mut self.0
	}
	}

	// FIXME: Probably a bad idea (in the threaded case)
	impl<T: Clone> Clone for MTLock<T> {
	#[inline]
	fn clone(&self) -> Self {
	MTLock(self.0.clone())
	}
	}
	} else {
	pub use std::marker::Send as Send;
	pub use std::marker::Sync as Sync;

	pub use parking_lot::RwLockReadGuard as ReadGuard;
	pub use parking_lot::MappedRwLockReadGuard as MappedReadGuard;
	pub use parking_lot::RwLockWriteGuard as WriteGuard;
	pub use parking_lot::MappedRwLockWriteGuard as MappedWriteGuard;

	pub use parking_lot::MutexGuard as LockGuard;
	pub use parking_lot::MappedMutexGuard as MappedLockGuard;

	pub use std::sync::atomic::{AtomicBool, AtomicUsize, AtomicU32, AtomicU64};

	pub use crossbeam_utils::atomic::AtomicCell;

	pub use std::sync::Arc as Lrc;
	pub use std::sync::Weak as Weak;

	pub type MTRef<'a, T> = &'a T;

	#[derive(Debug, Default)]
	pub struct MTLock<T>(Lock<T>);

	impl<T> MTLock<T> {
	#[inline(always)]
	pub fn new(inner: T) -> Self {
	MTLock(Lock::new(inner))
	}

	#[inline(always)]
	pub fn into_inner(self) -> T {
	self.0.into_inner()
	}

	#[inline(always)]
	pub fn get_mut(&mut self) -> &mut T {
	self.0.get_mut()
	}

	#[inline(always)]
	pub fn lock(&self) -> LockGuard<'_, T> {
	self.0.lock()
	}

	#[inline(always)]
	pub fn lock_mut(&self) -> LockGuard<'_, T> {
	self.lock()
	}
	}

	use parking_lot::Mutex as InnerLock;
	use parking_lot::RwLock as InnerRwLock;

	use std;
	use std::thread;
	pub use rayon::{join, scope};

	/// Runs a list of blocks in parallel. The first block is executed immediately on
	/// the current thread. Use that for the longest running block.
	#[macro_export]
	macro_rules! parallel {
	(impl $fblock:tt [$($c:tt,)] [$block:tt $(, $rest:tt)]) => {
	parallel!(impl $fblock [$block, $($c,)] [$($rest),])
	};
	(impl $fblock:tt [$($blocks:tt,)*] []) => {
	::rustc_data_structures::sync::scope(\|s\| {
	$(
	s.spawn(\|_\| $blocks);
	)*
	$fblock;
	})
	};
	($fblock:tt, $($blocks:tt),*) => {
	// Reverse the order of the later blocks since Rayon executes them in reverse order
	// when using a single thread. This ensures the execution order matches that
	// of a single threaded rustc
	parallel!(impl $fblock [] [$($blocks),*]);
	};
	}

	pub use rayon_core::WorkerLocal;

	pub use rayon::iter::ParallelIterator;
	use rayon::iter::IntoParallelIterator;

	pub fn par_iter<T: IntoParallelIterator>(t: T) -> T::Iter {
	t.into_par_iter()
	}

	pub fn par_for_each_in<T: IntoParallelIterator>(
	t: T,
	for_each: impl Fn(
	<<T as IntoParallelIterator>::Iter as ParallelIterator>::Item
	) + Sync + Send
	) {
	t.into_par_iter().for_each(for_each)
	}

	pub type MetadataRef = OwningRef<Box<dyn Erased + Send + Sync>, [u8]>;

	/// This makes locks panic if they are already held.
	/// It is only useful when you are running in a single thread
	const ERROR_CHECKING: bool = false;

	#[macro_export]
	macro_rules! rustc_erase_owner {
	($v:expr) => {{
	let v = $v;
	::rustc_data_structures::sync::assert_send_val(&v);
	v.erase_send_sync_owner()
	}}
	}
	}
	}

	pub fn assert_sync<T: ?Sized + Sync>() {}
	pub fn assert_send<T: ?Sized + Send>() {}
	pub fn assert_send_val<T: ?Sized + Send>(_t: &T) {}
	pub fn assert_send_sync_val<T: ?Sized + Sync + Send>(_t: &T) {}

	pub trait HashMapExt<K, V> {
	/// Same as HashMap::insert, but it may panic if there's already an
	/// entry for `key` with a value not equal to `value`
	fn insert_same(&mut self, key: K, value: V);
	}

	impl<K: Eq + Hash, V: Eq, S: BuildHasher> HashMapExt<K, V> for HashMap<K, V, S> {
	fn insert_same(&mut self, key: K, value: V) {
	self.entry(key).and_modify(\|old\| assert!(*old == value)).or_insert(value);
	}
	}

	/// A type whose inner value can be written once and then will stay read-only
	// This contains a PhantomData<T> since this type conceptually owns a T outside the Mutex once
	// initialized. This ensures that Once<T> is Sync only if T is. If we did not have PhantomData<T>
	// we could send a &Once<Cell<bool>> to multiple threads and call `get` on it to get access
	// to &Cell<bool> on those threads.
	pub struct Once<T>(Lock<Option<T>>, PhantomData<T>);

	impl<T> Once<T> {
	/// Creates an Once value which is uninitialized
	#[inline(always)]
	pub fn new() -> Self {
	Once(Lock::new(None), PhantomData)
	}

	/// Consumes the value and returns Some(T) if it was initialized
	#[inline(always)]
	pub fn into_inner(self) -> Option<T> {
	self.0.into_inner()
	}

	/// Tries to initialize the inner value to `value`.
	/// Returns `None` if the inner value was uninitialized and `value` was consumed setting it
	/// otherwise if the inner value was already set it returns `value` back to the caller
	#[inline]
	pub fn try_set(&self, value: T) -> Option<T> {
	let mut lock = self.0.lock();
	if lock.is_some() {
	return Some(value);
	}
	*lock = Some(value);
	None
	}

	/// Tries to initialize the inner value to `value`.
	/// Returns `None` if the inner value was uninitialized and `value` was consumed setting it
	/// otherwise if the inner value was already set it asserts that `value` is equal to the inner
	/// value and then returns `value` back to the caller
	#[inline]
	pub fn try_set_same(&self, value: T) -> Option<T> where T: Eq {
	let mut lock = self.0.lock();
	if let Some(ref inner) = *lock {
	assert!(*inner == value);
	return Some(value);
	}
	*lock = Some(value);
	None
	}

	/// Tries to initialize the inner value to `value` and panics if it was already initialized
	#[inline]
	pub fn set(&self, value: T) {
	assert!(self.try_set(value).is_none());
	}

	/// Tries to initialize the inner value by calling the closure while ensuring that no-one else
	/// can access the value in the mean time by holding a lock for the duration of the closure.
	/// If the value was already initialized the closure is not called and `false` is returned,
	/// otherwise if the value from the closure initializes the inner value, `true` is returned
	#[inline]
	pub fn init_locking<F: FnOnce() -> T>(&self, f: F) -> bool {
	let mut lock = self.0.lock();
	if lock.is_some() {
	return false;
	}
	*lock = Some(f());
	true
	}

	/// Tries to initialize the inner value by calling the closure without ensuring that no-one
	/// else can access it. This mean when this is called from multiple threads, multiple
	/// closures may concurrently be computing a value which the inner value should take.
	/// Only one of these closures are used to actually initialize the value.
	/// If some other closure already set the value,
	/// we return the value our closure computed wrapped in a `Option`.
	/// If our closure set the value, `None` is returned.
	/// If the value is already initialized, the closure is not called and `None` is returned.
	#[inline]
	pub fn init_nonlocking<F: FnOnce() -> T>(&self, f: F) -> Option<T> {
	if self.0.lock().is_some() {
	None
	} else {
	self.try_set(f())
	}
	}

	/// Tries to initialize the inner value by calling the closure without ensuring that no-one
	/// else can access it. This mean when this is called from multiple threads, multiple
	/// closures may concurrently be computing a value which the inner value should take.
	/// Only one of these closures are used to actually initialize the value.
	/// If some other closure already set the value, we assert that it our closure computed
	/// a value equal to the value already set and then
	/// we return the value our closure computed wrapped in a `Option`.
	/// If our closure set the value, `None` is returned.
	/// If the value is already initialized, the closure is not called and `None` is returned.
	#[inline]
	pub fn init_nonlocking_same<F: FnOnce() -> T>(&self, f: F) -> Option<T> where T: Eq {
	if self.0.lock().is_some() {
	None
	} else {
	self.try_set_same(f())
	}
	}

	/// Tries to get a reference to the inner value, returns `None` if it is not yet initialized
	#[inline(always)]
	pub fn try_get(&self) -> Option<&T> {
	let lock = &*self.0.lock();
	if let Some(ref inner) = *lock {
	// This is safe since we won't mutate the inner value
	unsafe { Some(&(inner as const T)) }
	} else {
	None
	}
	}

	/// Gets reference to the inner value, panics if it is not yet initialized
	#[inline(always)]
	pub fn get(&self) -> &T {
	self.try_get().expect("value was not set")
	}

	/// Gets reference to the inner value, panics if it is not yet initialized
	#[inline(always)]
	pub fn borrow(&self) -> &T {
	self.get()
	}
	}

	#[derive(Debug)]
	pub struct Lock<T>(InnerLock<T>);

	impl<T> Lock<T> {
	#[inline(always)]
	pub fn new(inner: T) -> Self {
	Lock(InnerLock::new(inner))
	}

	#[inline(always)]
	pub fn into_inner(self) -> T {
	self.0.into_inner()
	}

	#[inline(always)]
	pub fn get_mut(&mut self) -> &mut T {
	self.0.get_mut()
	}

	#[cfg(parallel_compiler)]
	#[inline(always)]
	pub fn try_lock(&self) -> Option<LockGuard<'_, T>> {
	self.0.try_lock()
	}

	#[cfg(not(parallel_compiler))]
	#[inline(always)]
	pub fn try_lock(&self) -> Option<LockGuard<'_, T>> {
	self.0.try_borrow_mut().ok()
	}

	#[cfg(parallel_compiler)]
	#[inline(always)]
	pub fn lock(&self) -> LockGuard<'_, T> {
	if ERROR_CHECKING {
	self.0.try_lock().expect("lock was already held")
	} else {
	self.0.lock()
	}
	}

	#[cfg(not(parallel_compiler))]
	#[inline(always)]
	pub fn lock(&self) -> LockGuard<'_, T> {
	self.0.borrow_mut()
	}

	#[inline(always)]
	pub fn with_lock<F: FnOnce(&mut T) -> R, R>(&self, f: F) -> R {
	f(&mut *self.lock())
	}

	#[inline(always)]
	pub fn borrow(&self) -> LockGuard<'_, T> {
	self.lock()
	}

	#[inline(always)]
	pub fn borrow_mut(&self) -> LockGuard<'_, T> {
	self.lock()
	}
	}

	impl<T: Default> Default for Lock<T> {
	#[inline]
	fn default() -> Self {
	Lock::new(T::default())
	}
	}

	// FIXME: Probably a bad idea
	impl<T: Clone> Clone for Lock<T> {
	#[inline]
	fn clone(&self) -> Self {
	Lock::new(self.borrow().clone())
	}
	}

	#[derive(Debug)]
	pub struct RwLock<T>(InnerRwLock<T>);

	impl<T> RwLock<T> {
	#[inline(always)]
	pub fn new(inner: T) -> Self {
	RwLock(InnerRwLock::new(inner))
	}

	#[inline(always)]
	pub fn into_inner(self) -> T {
	self.0.into_inner()
	}

	#[inline(always)]
	pub fn get_mut(&mut self) -> &mut T {
	self.0.get_mut()
	}

	#[cfg(not(parallel_compiler))]
	#[inline(always)]
	pub fn read(&self) -> ReadGuard<'_, T> {
	self.0.borrow()
	}

	#[cfg(parallel_compiler)]
	#[inline(always)]
	pub fn read(&self) -> ReadGuard<'_, T> {
	if ERROR_CHECKING {
	self.0.try_read().expect("lock was already held")
	} else {
	self.0.read()
	}
	}

	#[inline(always)]
	pub fn with_read_lock<F: FnOnce(&T) -> R, R>(&self, f: F) -> R {
	f(&*self.read())
	}

	#[cfg(not(parallel_compiler))]
	#[inline(always)]
	pub fn try_write(&self) -> Result<WriteGuard<'_, T>, ()> {
	self.0.try_borrow_mut().map_err(\|_\| ())
	}

	#[cfg(parallel_compiler)]
	#[inline(always)]
	pub fn try_write(&self) -> Result<WriteGuard<'_, T>, ()> {
	self.0.try_write().ok_or(())
	}

	#[cfg(not(parallel_compiler))]
	#[inline(always)]
	pub fn write(&self) -> WriteGuard<'_, T> {
	self.0.borrow_mut()
	}

	#[cfg(parallel_compiler)]
	#[inline(always)]
	pub fn write(&self) -> WriteGuard<'_, T> {
	if ERROR_CHECKING {
	self.0.try_write().expect("lock was already held")
	} else {
	self.0.write()
	}
	}

	#[inline(always)]
	pub fn with_write_lock<F: FnOnce(&mut T) -> R, R>(&self, f: F) -> R {
	f(&mut *self.write())
	}

	#[inline(always)]
	pub fn borrow(&self) -> ReadGuard<'_, T> {
	self.read()
	}

	#[inline(always)]
	pub fn borrow_mut(&self) -> WriteGuard<'_, T> {
	self.write()
	}
	}

	// FIXME: Probably a bad idea
	impl<T: Clone> Clone for RwLock<T> {
	#[inline]
	fn clone(&self) -> Self {
	RwLock::new(self.borrow().clone())
	}
	}

	/// A type which only allows its inner value to be used in one thread.
	/// It will panic if it is used on multiple threads.
	#[derive(Copy, Clone, Hash, Debug, Eq, PartialEq)]
	pub struct OneThread<T> {
	#[cfg(parallel_compiler)]
	thread: thread::ThreadId,
	inner: T,
	}

	#[cfg(parallel_compiler)]
	unsafe impl<T> std::marker::Sync for OneThread<T> {}
	#[cfg(parallel_compiler)]
	unsafe impl<T> std::marker::Send for OneThread<T> {}

	impl<T> OneThread<T> {
	#[inline(always)]
	fn check(&self) {
	#[cfg(parallel_compiler)]
	assert_eq!(thread::current().id(), self.thread);
	}

	#[inline(always)]
	pub fn new(inner: T) -> Self {
	OneThread {
	#[cfg(parallel_compiler)]
	thread: thread::current().id(),
	inner,
	}
	}

	#[inline(always)]
	pub fn into_inner(value: Self) -> T {
	value.check();
	value.inner
	}
	}

	impl<T> Deref for OneThread<T> {
	type Target = T;

	fn deref(&self) -> &T {
	self.check();
	&self.inner
	}
	}

	impl<T> DerefMut for OneThread<T> {
	fn deref_mut(&mut self) -> &mut T {
	self.check();
	&mut self.inner
	}
	}