Weak reference

In computer programming, a weak reference is a reference that does not protect the referenced object from collection by a garbage collector; unlike a strong reference. An object referenced only by weak references is considered unreachable (or weakly reachable) and so may be collected at any time. Some garbage-collected languages feature or support various levels of weak references, such as Java, C#, Python, Perl, and Lisp.

1 Garbage collection
2 Variations
3 Examples
4 See also
5 Notes
6 External links

Garbage collection

Main article: Garbage collection (computer science)

Garbage collection is used to clean up unused objects and so reduce the potential for memory leaks and data corruption. There are two main types of garbage collection: tracing and reference counting. Reference counting schemes record the number of references to a given object and collect the object when the reference count becomes zero. Reference-counting cannot collect cyclic (or circular) references because only one object may be collected at a time. Groups of mutually referencing objects which are not directly referenced by other objects and are unreachable can thus become permanently resident; if an application continually generates such unreachable groups of unreachable objects this will have the effect of a memory leak. Weak references (references which are not counted in reference counting) may be used to solve the problem of circular references if the reference cycles are avoided by using weak references for some of the references within the group. For example, Apple's Cocoa framework recommends this approach, by using strong references for parent-to-child references, and weak references for child-to-parent references, thus avoiding cycles.[1]

Weak references are also used to minimize the number of unnecessary objects in memory by allowing the program to indicate which objects are little important by only weakly referencing them.

Variations

Some languages have multiple levels of weak reference strength. For example, Java has, in order of decreasing strength, soft, weak, and phantom references, defined in the package java.lang.ref.^[1] Each reference type has an associated notion of reachability. The garbage collector (GC) uses an object's type of reachability to determine when to free the object. It is safe for the GC to free an object that is softly reachable, but the GC may decide not to do so if it believes the JVM can spare the memory (e.g. the JVM has lots of unused heap space). The GC will free a weakly reachable object as soon as the GC notices the object. Unlike the other reference types, a phantom reference cannot be followed. On the other hand, phantom references provide a mechanism to notify the program when an object has been freed (notification is implemented using ReferenceQueues).

Some non-garbage-collected languages, such as C++, provide weak/strong reference functionality as part of supporting garbage collection libraries. In the case of C++, normal pointers are weak and smart pointers are strong; although pointers are not true weak references, as weak references are supposed to know when the object becomes unreachable.

Examples

Weak references can be useful in keeping track of the current variables being referenced in the application. This^[which?]} list must have weak links to the objects. Otherwise, once objects are added to the list, they will be referenced by it and will persist forever (or until the program stops).

Java

Java was the first main language to introduce strong reference as the default object reference. Previously (ANSI) C only had weak references. However it was noted by David Hostettler Wain and Scott Alexander Nesmith that event trees were not evaporating properly. Thus strong/weak references of counted and uncounted references was derived (~1998).

If a weak reference is created, and then elsewhere in the code get() is used to get the actual object, the weak reference isn't strong enough to prevent garbage collection, so it may be (if there are no strong references to the object) that get() suddenly starts returning null.^[2]

import java.lang.ref.WeakReference; public class ReferenceTest { public static void main(String[] args) throws InterruptedException { WeakReference r = new WeakReference(new String("I'm here")); WeakReference sr = new WeakReference("I'm here"); System.out.println("before gc: r=" + r.get() + ", static=" + sr.get()); System.gc(); Thread.sleep(100); // only r.get() becomes null System.out.println("after gc: r=" + r.get() + ", static=" + sr.get()); }}

Another use of weak references is in writing a cache. Using, for example, a weak hash map, one can store in the cache the various referred objects via a weak reference. When the garbage collector runs — when for example the application's memory usage gets sufficiently high — those cached objects which are no longer directly referenced by other objects are removed from the cache.

Smalltalk

|a s1 s2| s1 := 'hello' copy. "that's a strong reference"s2 := 'world' copy. "that's a strong reference"a := WeakArray with:s1 with:s2.a printOn: Transcript. ObjectMemory collectGarbage.a printOn: Transcript.  "both elements still there" s1 := nil.  "strong reference goes away" ObjectMemory collectGarbage.a printOn: Transcript.  "first element gone" s2 := nil.  "strong reference goes away" ObjectMemory collectGarbage.a printOn: Transcript.  "second element gone"

Lua

weak_table = setmetatable({}, {__mode="v"})weak_table.item = {}print(weak_table.item)collectgarbage()print(weak_table.item)

Objective-C 2.0

In Objective-C 2.0, not only garbage collector, but also automatic reference counting will be affected by weak references. All variables and properties in the following example are weak.

@interface WeakRef : NSObject{ __weak NSString *str1; __assign NSString *str2;} @property (nonatomic, weak) NSString *str3;@property (nonatomic, assign) NSString *str4; @end

The difference between weak (__weak) and assign (__assign) is that when the object the variable pointed to is being deallocated, whether the value of the variable is going to be changed or not. weak ones will be updated to nil and the assign one will be left unchanged, as a dangling pointer. The weak references is added to Objective-C since Mac OS X 10.7 "Li on" and iOS 5, together with Xcode 4.1 (4.2 for iOS). Older versions of Mac OS X, iOS, and GNUstep support only assign references as weak ones.

Vala

class Node { public weak Node prev; // a weak reference is used to avoid circular references between nodes of a list public Node next;}

Notes

^ Nicholas, Ethan. "Understanding Weak References". java.net. published on May 4, 2006. accessed on October 1, 2010
^ weblogs.java.net Java Examples

External links

Java developer article: 'Reference Objects and Garbage Collection'
Understanding Weak References
RCache - Java Library for weak/soft reference based cache
Python Weak References
Fred L. Drake, Jr., PEP 205: Weak References, Python Enhancement Proposal, January 2001.
Java theory and practice: Plugging memory leaks with weak references
Boost 1.48 weak_ptr Reference

Memory management

Manual memory management	delete (C++) C dynamic memory allocation new (C++) Static memory allocation

Virtual memory	Demand paging Page table Paging

Hardware	Memory management unit Translation lookaside buffer

Garbage collection	Boehm garbage collector Finalizer Garbage Mark-compact algorithm Reference counting Strong reference Weak reference

Memory segmentation	Protected mode Real mode Virtual 8086 mode x86 memory segmentation

Memory safety	Buffer overflow Dangling pointer Stack overflow

Issues	Fragmentation Memory leak Unreachable memory

Other	Automatic variable International Symposium on Memory Management Region-based memory management

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