Thread-local storage
Thread-local storage is a computer programming method that uses static or global memory local to a thread.
While the use of global variables is generally discouraged in modern programming, legacy operating systems such as UNIX are designed for uniprocessor hardware and require some additional mechanism to retain the semantics of pre-reentrant APIs. An example of such situations is where functions use a global variable to set an error condition. If
errno
were a global variable, a call of a system function on one thread may overwrite the value previously set by a call of a system function on a different thread, possibly before following code on that different thread could check for the error condition. The solution is to have errno
be a variable that looks like it is global, but in fact exists once per thread—i.e., it lives in thread-local storage. A second use case would be multiple threads accumulating information into a global variable. To avoid a race condition, every access to this global variable would have to be protected by a mutex. Alternatively, each thread might accumulate into a thread-local variable. Threads then only have to synchronise a final accumulation from their own thread-local variable into a single, truly global variable.Many systems impose restrictions on the size of the thread-local memory block, in fact often rather tight limits. On the other hand, if a system can provide at least a memory address sized variable thread-local, then this allows the use of arbitrarily sized memory blocks in a thread-local manner, by allocating such a memory block dynamically and storing the memory address of that block in the thread-local variable.
Windows implementation
The application programming interface functionTlsAlloc
can be used to obtain an unused TLS slot index; the TLS slot index will then be considered ‘used’.The
TlsGetValue
and TlsSetValue
functions are then used to read and write a memory address to a thread-local variable identified by the TLS slot index. TlsSetValue
only affects the variable for the current thread. The TlsFree
function can be called to release the TLS slot index.There is a Win32 Thread Information Block for each thread. One of the entries in this block is the thread-local storage table for that thread.
TlsAlloc returns an index to this table, unique per address space, for each call. Each thread has its own copy of the thread-local storage table. Hence, each thread can independently use TlsSetValue and obtain the specified value via TlsGetValue, because these set and look up an entry in the thread's own table.
Apart from TlsXxx function family, Windows executables can define a section which is mapped to a different page for each thread of the executing process. Unlike TlsXxx values, these pages can contain arbitrary and valid addresses. These addresses, however, are different for each executing thread and therefore should not be passed to asynchronous functions or otherwise passed to code which assume that a virtual address is unique within the whole process. TLS sections are managed using memory paging and its size is quantized to a page size.
Such sections may only be defined inside a main executable of a program - DLLs should not contain such sections, because they are not correctly initialized when loading with LoadLibrary.
Pthreads implementation
In the Pthreads API, memory local to a thread is designated with the term Thread-specific data.The functions
pthread_key_create
and pthread_key_delete
are used respectively to create and delete a key for thread-specific data. The type of the key is explicitly left opaque and is referred to as pthread_key_t
. This key can be seen by all threads. In each thread, the key can be associated with thread-specific data via pthread_setspecific
. The data can later be retrieved using pthread_getspecific
.In addition
pthread_key_create
can optionally accept a destructor function that will automatically be called at thread exit, if the thread-specific data is not NULL. The destructor receives the value associated with the key as parameter so it can perform cleanup actions. Even when a destructor is specified, the program must still call pthread_key_delete
to free the thread-specific data at process level.Language-specific implementation
Apart from relying on programmers to call the appropriate API functions, it is also possible to extend the programming language to support thread local storage.C and C++
In C11, the keyword_Thread_local
is used to define thread-local variables. The header
, if supported, defines thread_local
as a synonym for that keyword. Example usage:- include
C++11 introduces the
thread_local
keyword which can be used in the following cases- Namespace level variables
- File static variables
- Function static variables
- Static member variables
- Solaris Studio C/C++, IBM XL C/C++, GNU C, Clang and Intel C++ Compiler use the syntax:
- :
__thread int number;
- Visual C++, Intel C/C++, C++Builder, and Digital Mars C++ use the syntax:
- :
__declspec int number;
- C++Builder also supports the syntax:
- :
int __thread number;
__declspec
works in DLLs only when those DLLs are bound to the executable, and will not work for those loaded with LoadLibrary.Common Lisp (and maybe other dialects)
provides a feature called dynamically scoped variables.Dynamic variables have a binding which is private to the invocation of a function and all of the children called by that function.
This abstraction naturally maps to thread-specific storage, and Lisp implementations that provide threads do this. Common Lisp has numerous standard dynamic variables, and so threads cannot be sensibly added to an implementation of the language without these variables having thread-local semantics in dynamic binding.
For instance the standard variable
*print-base*
determines the default radix in which integers are printed. If this variable is overridden, then all enclosing code will print integers in an alternate radix:;; in hexadecimal:
) )
If functions can execute concurrently on different threads, this binding has to be properly thread-local, otherwise each thread will fight over who controls a global printing radix.
D
In D version 2, all static and global variables are thread-local by default and are declared with syntax similar to "normal" global and static variables in other languages. Global variables must be explicitly requested using the shared keyword:int threadLocal; // This is a thread-local variable.
shared int global; // This is a global variable shared with all threads.
The shared keyword works both as the storage class, and as a type qualifier – shared variables are subject to some restrictions which statically enforce data integrity. To declare a "classic" global variable without these restrictions, the unsafe __gshared keyword must be used:
__gshared int global; // This is a plain old global variable.
Java
In Java, thread-local variables are implemented by the class object. ThreadLocal holds variable of type T, which is accessible via get/set methods. For example, ThreadLocal variable holding Integer value looks like this:private static final ThreadLocal
At least for Oracle/OpenJDK, this does not use native thread-local storage in spite of OS threads being used for other aspects of Java threading. Instead, each Thread object stores a map of ThreadLocal objects to their values.
.NET languages: C# and others
In.NET Framework languages such as C#, static fields can be marked with the:
class FooBar
In.NET 4.0 the class is available for allocating and lazily loading thread-local variables.
class FooBar
Also
is available for dynamically allocating thread-local variables.
Object Pascal
In Object Pascal or Free Pascal the threadvar reserved keyword can be used instead of 'var' to declare variables using the thread-local storage.var
mydata_process: integer;
threadvar
mydata_threadlocal: integer;
Objective-C
In Cocoa, GNUstep, and OpenStep, each NSThread object has a thread-local dictionary that can be accessed through the thread's threadDictionary method.NSMutableDictionary *dict = NSThread currentThread] threadDictionary];
dict = @"Some data";
Perl
In Perl threads were added late in the evolution of the language, after a large body of extant code was already present on the Comprehensive Perl Archive Network. Thus, threads in Perl by default take their own local storage for all variables, to minimise the impact of threads on extant non-thread-aware code. In Perl, a thread-shared variable can be created using an attribute:use threads;
use threads::shared;
my $localvar;
my $sharedvar :shared;
PureBasic
In PureBasic thread variables are declared with the keyword .Threaded Var
Python
In Python version 2.4 or later, local class in threading module can be used to create thread-local storage.import threading
mydata = threading.local
mydata.x = 1
Ruby
can create/access thread-local variables using =/ methods:Thread.current = 1
Rust
can create/access thread-local variables using the thread_local! macro in the std::thread module of the :use std::cell::RefCell;
use std::thread;
thread_local!;
FOO.with;
// each thread starts out with the initial value of 1, even though this thread already changed its copy of the thread local value to 2
let t = thread::spawn;
// wait for the thread to complete and bail out on panic
t.join.unwrap;
// original thread retains the original value of 2 despite the child thread changing the value to 3 for that thread
FOO.with;