// Copyright 2014-2015 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! Thread local storage //! //! This module provides an implementation of thread local storage for Rust //! programs. Thread local storage is a method of storing data into a global //! variable which each thread in the program will have its own copy of. //! Threads do not share this data, so accesses do not need to be synchronized. //! //! At a high level, this module provides two variants of storage: //! //! * Owning thread local storage. This is a type of thread local key which //! owns the value that it contains, and will destroy the value when the //! thread exits. This variant is created with the `thread_local!` macro and //! can contain any value which is `'static` (no borrowed pointers. //! //! * Scoped thread local storage. This type of key is used to store a reference //! to a value into local storage temporarily for the scope of a function //! call. There are no restrictions on what types of values can be placed //! into this key. //! //! Both forms of thread local storage provide an accessor function, `with`, //! which will yield a shared reference to the value to the specified //! closure. Thread local keys only allow shared access to values as there is no //! way to guarantee uniqueness if a mutable borrow was allowed. Most values //! will want to make use of some form of **interior mutability** through the //! `Cell` or `RefCell` types. #![macro_escape] #![stable] use prelude::v1::*; use cell::UnsafeCell; pub mod scoped; // Sure wish we had macro hygiene, no? #[doc(hidden)] pub mod __impl { pub use super::imp::Key as KeyInner; pub use super::imp::destroy_value; pub use sys_common::thread_local::INIT_INNER as OS_INIT_INNER; pub use sys_common::thread_local::StaticKey as OsStaticKey; } /// A thread local storage key which owns its contents. /// /// This key uses the fastest possible implementation available to it for the /// target platform. It is instantiated with the `thread_local!` macro and the /// primary method is the `with` method. /// /// The `with` method yields a reference to the contained value which cannot be /// sent across tasks or escape the given closure. /// /// # Initialization and Destruction /// /// Initialization is dynamically performed on the first call to `with()` /// within a thread, and values support destructors which will be run when a /// thread exits. /// /// # Example /// /// ``` /// use std::cell::RefCell; /// use std::thread::Thread; /// /// thread_local!(static FOO: RefCell = RefCell::new(1)); /// /// FOO.with(|f| { /// assert_eq!(*f.borrow(), 1); /// *f.borrow_mut() = 2; /// }); /// /// // each thread starts out with the initial value of 1 /// Thread::spawn(move|| { /// FOO.with(|f| { /// assert_eq!(*f.borrow(), 1); /// *f.borrow_mut() = 3; /// }); /// }).detach(); /// /// // we retain our original value of 2 despite the child thread /// FOO.with(|f| { /// assert_eq!(*f.borrow(), 2); /// }); /// ``` #[stable] pub struct Key { // The key itself may be tagged with #[thread_local], and this `Key` is // stored as a `static`, and it's not valid for a static to reference the // address of another thread_local static. For this reason we kinda wonkily // work around this by generating a shim function which will give us the // address of the inner TLS key at runtime. // // This is trivially devirtualizable by LLVM because we never store anything // to this field and rustc can declare the `static` as constant as well. #[doc(hidden)] pub inner: fn() -> &'static __impl::KeyInner>>, // initialization routine to invoke to create a value #[doc(hidden)] pub init: fn() -> T, } /// Declare a new thread local storage key of type `std::thread_local::Key`. #[macro_export] #[stable] macro_rules! thread_local { (static $name:ident: $t:ty = $init:expr) => ( static $name: ::std::thread_local::Key<$t> = { use std::cell::UnsafeCell as __UnsafeCell; use std::thread_local::__impl::KeyInner as __KeyInner; use std::option::Option as __Option; use std::option::Option::None as __None; __thread_local_inner!(static __KEY: __UnsafeCell<__Option<$t>> = { __UnsafeCell { value: __None } }); fn __init() -> $t { $init } fn __getit() -> &'static __KeyInner<__UnsafeCell<__Option<$t>>> { &__KEY } ::std::thread_local::Key { inner: __getit, init: __init } }; ); (pub static $name:ident: $t:ty = $init:expr) => ( pub static $name: ::std::thread_local::Key<$t> = { use std::cell::UnsafeCell as __UnsafeCell; use std::thread_local::__impl::KeyInner as __KeyInner; use std::option::Option as __Option; use std::option::Option::None as __None; __thread_local_inner!(static __KEY: __UnsafeCell<__Option<$t>> = { __UnsafeCell { value: __None } }); fn __init() -> $t { $init } fn __getit() -> &'static __KeyInner<__UnsafeCell<__Option<$t>>> { &__KEY } ::std::thread_local::Key { inner: __getit, init: __init } }; ); } // Macro pain #4586: // // When cross compiling, rustc will load plugins and macros from the *host* // platform before search for macros from the target platform. This is primarily // done to detect, for example, plugins. Ideally the macro below would be // defined once per module below, but unfortunately this means we have the // following situation: // // 1. We compile libstd for x86_64-unknown-linux-gnu, this thread_local!() macro // will inject #[thread_local] statics. // 2. We then try to compile a program for arm-linux-androideabi // 3. The compiler has a host of linux and a target of android, so it loads // macros from the *linux* libstd. // 4. The macro generates a #[thread_local] field, but the android libstd does // not use #[thread_local] // 5. Compile error about structs with wrong fields. // // To get around this, we're forced to inject the #[cfg] logic into the macro // itself. Woohoo. #[macro_export] #[doc(hidden)] macro_rules! __thread_local_inner { (static $name:ident: $t:ty = $init:expr) => ( #[cfg_attr(all(any(target_os = "macos", target_os = "linux"), not(target_arch = "aarch64")), thread_local)] static $name: ::std::thread_local::__impl::KeyInner<$t> = __thread_local_inner!($init, $t); ); (pub static $name:ident: $t:ty = $init:expr) => ( #[cfg_attr(all(any(target_os = "macos", target_os = "linux"), not(target_arch = "aarch64")), thread_local)] pub static $name: ::std::thread_local::__impl::KeyInner<$t> = __thread_local_inner!($init, $t); ); ($init:expr, $t:ty) => ({ #[cfg(all(any(target_os = "macos", target_os = "linux"), not(target_arch = "aarch64")))] const _INIT: ::std::thread_local::__impl::KeyInner<$t> = { ::std::thread_local::__impl::KeyInner { inner: ::std::cell::UnsafeCell { value: $init }, dtor_registered: ::std::cell::UnsafeCell { value: false }, dtor_running: ::std::cell::UnsafeCell { value: false }, } }; #[cfg(any(not(any(target_os = "macos", target_os = "linux")), target_arch = "aarch64"))] const _INIT: ::std::thread_local::__impl::KeyInner<$t> = { unsafe extern fn __destroy(ptr: *mut u8) { ::std::thread_local::__impl::destroy_value::<$t>(ptr); } ::std::thread_local::__impl::KeyInner { inner: ::std::cell::UnsafeCell { value: $init }, os: ::std::thread_local::__impl::OsStaticKey { inner: ::std::thread_local::__impl::OS_INIT_INNER, dtor: ::std::option::Option::Some(__destroy as unsafe extern fn(*mut u8)), }, } }; _INIT }); } /// Indicator of the state of a thread local storage key. #[unstable = "state querying was recently added"] #[derive(Eq, PartialEq, Copy)] pub enum State { /// All keys are in this state whenever a thread starts. Keys will /// transition to the `Valid` state once the first call to `with` happens /// and the initialization expression succeeds. /// /// Keys in the `Uninitialized` state will yield a reference to the closure /// passed to `with` so long as the initialization routine does not panic. Uninitialized, /// Once a key has been accessed successfully, it will enter the `Valid` /// state. Keys in the `Valid` state will remain so until the thread exits, /// at which point the destructor will be run and the key will enter the /// `Destroyed` state. /// /// Keys in the `Valid` state will be guaranteed to yield a reference to the /// closure passed to `with`. Valid, /// When a thread exits, the destructors for keys will be run (if /// necessary). While a destructor is running, and possibly after a /// destructor has run, a key is in the `Destroyed` state. /// /// Keys in the `Destroyed` states will trigger a panic when accessed via /// `with`. Destroyed, } impl Key { /// Acquire a reference to the value in this TLS key. /// /// This will lazily initialize the value if this thread has not referenced /// this key yet. /// /// # Panics /// /// This function will `panic!()` if the key currently has its /// destructor running, and it **may** panic if the destructor has /// previously been run for this thread. #[stable] pub fn with(&'static self, f: F) -> R where F: FnOnce(&T) -> R { let slot = (self.inner)(); unsafe { let slot = slot.get().expect("cannot access a TLS value during or \ after it is destroyed"); f(match *slot.get() { Some(ref inner) => inner, None => self.init(slot), }) } } unsafe fn init(&self, slot: &UnsafeCell>) -> &T { // Execute the initialization up front, *then* move it into our slot, // just in case initialization fails. let value = (self.init)(); let ptr = slot.get(); *ptr = Some(value); (*ptr).as_ref().unwrap() } /// Query the current state of this key. /// /// A key is initially in the `Uninitialized` state whenever a thread /// starts. It will remain in this state up until the first call to `with` /// within a thread has run the initialization expression successfully. /// /// Once the initialization expression succeeds, the key transitions to the /// `Valid` state which will guarantee that future calls to `with` will /// succeed within the thread. /// /// When a thread exits, each key will be destroyed in turn, and as keys are /// destroyed they will enter the `Destroyed` state just before the /// destructor starts to run. Keys may remain in the `Destroyed` state after /// destruction has completed. Keys without destructors (e.g. with types /// that are `Copy`), may never enter the `Destroyed` state. /// /// Keys in the `Uninitialized` can be accessed so long as the /// initialization does not panic. Keys in the `Valid` state are guaranteed /// to be able to be accessed. Keys in the `Destroyed` state will panic on /// any call to `with`. #[unstable = "state querying was recently added"] pub fn state(&'static self) -> State { unsafe { match (self.inner)().get() { Some(cell) => { match *cell.get() { Some(..) => State::Valid, None => State::Uninitialized, } } None => State::Destroyed, } } } /// Deprecated #[deprecated = "function renamed to state() and returns more info"] pub fn destroyed(&'static self) -> bool { self.state() == State::Destroyed } } #[cfg(all(any(target_os = "macos", target_os = "linux"), not(target_arch = "aarch64")))] mod imp { use prelude::v1::*; use cell::UnsafeCell; use intrinsics; use ptr; #[doc(hidden)] pub struct Key { // Place the inner bits in an `UnsafeCell` to currently get around the // "only Sync statics" restriction. This allows any type to be placed in // the cell. // // Note that all access requires `T: 'static` so it can't be a type with // any borrowed pointers still. pub inner: UnsafeCell, // Metadata to keep track of the state of the destructor. Remember that // these variables are thread-local, not global. pub dtor_registered: UnsafeCell, // should be Cell pub dtor_running: UnsafeCell, // should be Cell } unsafe impl ::kinds::Sync for Key { } #[doc(hidden)] impl Key { pub unsafe fn get(&'static self) -> Option<&'static T> { if intrinsics::needs_drop::() && *self.dtor_running.get() { return None } self.register_dtor(); Some(&*self.inner.get()) } unsafe fn register_dtor(&self) { if !intrinsics::needs_drop::() || *self.dtor_registered.get() { return } register_dtor(self as *const _ as *mut u8, destroy_value::); *self.dtor_registered.get() = true; } } // Since what appears to be glibc 2.18 this symbol has been shipped which // GCC and clang both use to invoke destructors in thread_local globals, so // let's do the same! // // Note, however, that we run on lots older linuxes, as well as cross // compiling from a newer linux to an older linux, so we also have a // fallback implementation to use as well. // // Due to rust-lang/rust#18804, make sure this is not generic! #[cfg(target_os = "linux")] unsafe fn register_dtor(t: *mut u8, dtor: unsafe extern fn(*mut u8)) { use mem; use libc; use sys_common::thread_local as os; extern { static __dso_handle: *mut u8; #[linkage = "extern_weak"] static __cxa_thread_atexit_impl: *const (); } if !__cxa_thread_atexit_impl.is_null() { type F = unsafe extern fn(dtor: unsafe extern fn(*mut u8), arg: *mut u8, dso_handle: *mut u8) -> libc::c_int; mem::transmute::<*const (), F>(__cxa_thread_atexit_impl) (dtor, t, __dso_handle); return } // The fallback implementation uses a vanilla OS-based TLS key to track // the list of destructors that need to be run for this thread. The key // then has its own destructor which runs all the other destructors. // // The destructor for DTORS is a little special in that it has a `while` // loop to continuously drain the list of registered destructors. It // *should* be the case that this loop always terminates because we // provide the guarantee that a TLS key cannot be set after it is // flagged for destruction. static DTORS: os::StaticKey = os::StaticKey { inner: os::INIT_INNER, dtor: Some(run_dtors as unsafe extern "C" fn(*mut u8)), }; type List = Vec<(*mut u8, unsafe extern fn(*mut u8))>; if DTORS.get().is_null() { let v: Box = box Vec::new(); DTORS.set(mem::transmute(v)); } let list: &mut List = &mut *(DTORS.get() as *mut List); list.push((t, dtor)); unsafe extern fn run_dtors(mut ptr: *mut u8) { while !ptr.is_null() { let list: Box = mem::transmute(ptr); for &(ptr, dtor) in list.iter() { dtor(ptr); } ptr = DTORS.get(); DTORS.set(0 as *mut _); } } } // OSX's analog of the above linux function is this _tlv_atexit function. // The disassembly of thread_local globals in C++ (at least produced by // clang) will have this show up in the output. #[cfg(target_os = "macos")] unsafe fn register_dtor(t: *mut u8, dtor: unsafe extern fn(*mut u8)) { extern { fn _tlv_atexit(dtor: unsafe extern fn(*mut u8), arg: *mut u8); } _tlv_atexit(dtor, t); } #[doc(hidden)] pub unsafe extern fn destroy_value(ptr: *mut u8) { let ptr = ptr as *mut Key; // Right before we run the user destructor be sure to flag the // destructor as running for this thread so calls to `get` will return // `None`. *(*ptr).dtor_running.get() = true; ptr::read((*ptr).inner.get() as *const T); } } #[cfg(any(not(any(target_os = "macos", target_os = "linux")), target_arch = "aarch64"))] mod imp { use prelude::v1::*; use cell::UnsafeCell; use mem; use sys_common::thread_local::StaticKey as OsStaticKey; #[doc(hidden)] pub struct Key { // Statically allocated initialization expression, using an `UnsafeCell` // for the same reasons as above. pub inner: UnsafeCell, // OS-TLS key that we'll use to key off. pub os: OsStaticKey, } unsafe impl ::kinds::Sync for Key { } struct Value { key: &'static Key, value: T, } #[doc(hidden)] impl Key { pub unsafe fn get(&'static self) -> Option<&'static T> { self.ptr().map(|p| &*p) } unsafe fn ptr(&'static self) -> Option<*mut T> { let ptr = self.os.get() as *mut Value; if !ptr.is_null() { if ptr as uint == 1 { return None } return Some(&mut (*ptr).value as *mut T); } // If the lookup returned null, we haven't initialized our own local // copy, so do that now. // // Also note that this transmute_copy should be ok because the value // `inner` is already validated to be a valid `static` value, so we // should be able to freely copy the bits. let ptr: Box> = box Value { key: self, value: mem::transmute_copy(&self.inner), }; let ptr: *mut Value = mem::transmute(ptr); self.os.set(ptr as *mut u8); Some(&mut (*ptr).value as *mut T) } } #[doc(hidden)] pub unsafe extern fn destroy_value(ptr: *mut u8) { // The OS TLS ensures that this key contains a NULL value when this // destructor starts to run. We set it back to a sentinel value of 1 to // ensure that any future calls to `get` for this thread will return // `None`. // // Note that to prevent an infinite loop we reset it back to null right // before we return from the destructor ourselves. let ptr: Box> = mem::transmute(ptr); let key = ptr.key; key.os.set(1 as *mut u8); drop(ptr); key.os.set(0 as *mut u8); } } #[cfg(test)] mod tests { use prelude::v1::*; use sync::mpsc::{channel, Sender}; use cell::UnsafeCell; use super::State; use thread::Thread; struct Foo(Sender<()>); impl Drop for Foo { fn drop(&mut self) { let Foo(ref s) = *self; s.send(()).unwrap(); } } #[test] fn smoke_no_dtor() { thread_local!(static FOO: UnsafeCell = UnsafeCell { value: 1 }); FOO.with(|f| unsafe { assert_eq!(*f.get(), 1); *f.get() = 2; }); let (tx, rx) = channel(); let _t = Thread::spawn(move|| { FOO.with(|f| unsafe { assert_eq!(*f.get(), 1); }); tx.send(()).unwrap(); }); rx.recv().unwrap(); FOO.with(|f| unsafe { assert_eq!(*f.get(), 2); }); } #[test] fn states() { struct Foo; impl Drop for Foo { fn drop(&mut self) { assert!(FOO.state() == State::Destroyed); } } fn foo() -> Foo { assert!(FOO.state() == State::Uninitialized); Foo } thread_local!(static FOO: Foo = foo()); Thread::spawn(|| { assert!(FOO.state() == State::Uninitialized); FOO.with(|_| { assert!(FOO.state() == State::Valid); }); assert!(FOO.state() == State::Valid); }).join().ok().unwrap(); } #[test] fn smoke_dtor() { thread_local!(static FOO: UnsafeCell> = UnsafeCell { value: None }); let (tx, rx) = channel(); let _t = Thread::spawn(move|| unsafe { let mut tx = Some(tx); FOO.with(|f| { *f.get() = Some(Foo(tx.take().unwrap())); }); }); rx.recv().unwrap(); } #[test] fn circular() { struct S1; struct S2; thread_local!(static K1: UnsafeCell> = UnsafeCell { value: None }); thread_local!(static K2: UnsafeCell> = UnsafeCell { value: None }); static mut HITS: uint = 0; impl Drop for S1 { fn drop(&mut self) { unsafe { HITS += 1; if K2.state() == State::Destroyed { assert_eq!(HITS, 3); } else { if HITS == 1 { K2.with(|s| *s.get() = Some(S2)); } else { assert_eq!(HITS, 3); } } } } } impl Drop for S2 { fn drop(&mut self) { unsafe { HITS += 1; assert!(K1.state() != State::Destroyed); assert_eq!(HITS, 2); K1.with(|s| *s.get() = Some(S1)); } } } Thread::spawn(move|| { drop(S1); }).join().ok().unwrap(); } #[test] fn self_referential() { struct S1; thread_local!(static K1: UnsafeCell> = UnsafeCell { value: None }); impl Drop for S1 { fn drop(&mut self) { assert!(K1.state() == State::Destroyed); } } Thread::spawn(move|| unsafe { K1.with(|s| *s.get() = Some(S1)); }).join().ok().unwrap(); } #[test] fn dtors_in_dtors_in_dtors() { struct S1(Sender<()>); thread_local!(static K1: UnsafeCell> = UnsafeCell { value: None }); thread_local!(static K2: UnsafeCell> = UnsafeCell { value: None }); impl Drop for S1 { fn drop(&mut self) { let S1(ref tx) = *self; unsafe { if K2.state() != State::Destroyed { K2.with(|s| *s.get() = Some(Foo(tx.clone()))); } } } } let (tx, rx) = channel(); let _t = Thread::spawn(move|| unsafe { let mut tx = Some(tx); K1.with(|s| *s.get() = Some(S1(tx.take().unwrap()))); }); rx.recv().unwrap(); } } #[cfg(test)] mod dynamic_tests { use prelude::v1::*; use cell::RefCell; use collections::HashMap; #[test] fn smoke() { fn square(i: int) -> int { i * i } thread_local!(static FOO: int = square(3)); FOO.with(|f| { assert_eq!(*f, 9); }); } #[test] fn hashmap() { fn map() -> RefCell> { let mut m = HashMap::new(); m.insert(1, 2); RefCell::new(m) } thread_local!(static FOO: RefCell> = map()); FOO.with(|map| { assert_eq!(map.borrow()[1], 2); }); } #[test] fn refcell_vec() { thread_local!(static FOO: RefCell> = RefCell::new(vec![1, 2, 3])); FOO.with(|vec| { assert_eq!(vec.borrow().len(), 3); vec.borrow_mut().push(4); assert_eq!(vec.borrow()[3], 4); }); } }