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WeakReference Class

Definition

Represents a weak reference, which references an object while still allowing that object to be reclaimed by garbage collection.

public ref class WeakReference
public ref class WeakReference : System::Runtime::Serialization::ISerializable
public class WeakReference
public class WeakReference : System.Runtime.Serialization.ISerializable
[System.Serializable]
public class WeakReference : System.Runtime.Serialization.ISerializable
[System.Serializable]
[System.Runtime.InteropServices.ComVisible(true)]
public class WeakReference : System.Runtime.Serialization.ISerializable
type WeakReference = class
type WeakReference = class
    interface ISerializable
[<System.Serializable>]
type WeakReference = class
    interface ISerializable
[<System.Serializable>]
[<System.Runtime.InteropServices.ComVisible(true)>]
type WeakReference = class
    interface ISerializable
Public Class WeakReference
Public Class WeakReference
Implements ISerializable
Inheritance
WeakReference
Attributes
Implements

Examples

The following example demonstrates how you can use weak references to maintain a cache of objects as a resource for an application. The cache is constructed using an IDictionary<TKey,TValue> of WeakReference objects keyed by an index value. The Target property for the WeakReference objects is an object in a byte array that represents data.

The example randomly accesses objects in the cache. If an object is reclaimed for garbage collection, a new data object is regenerated; otherwise, the object is available to access because of the weak reference.

using System;
using System.Collections.Generic;

public class Program
{
    public static void Main()
    {
        // Create the cache.
        int cacheSize = 50;
        Random r = new Random();
        Cache c = new Cache(cacheSize);

        string DataName = "";
        GC.Collect(0);

        // Randomly access objects in the cache.
        for (int i = 0; i < c.Count; i++) {
            int index = r.Next(c.Count);

            // Access the object by getting a property value.
            DataName = c[index].Name;
        }
        // Show results.
        double regenPercent = c.RegenerationCount/(double)c.Count;
        Console.WriteLine($"Cache size: {c.Count}, Regenerated: {regenPercent:P0}");
    }
}

public class Cache
{
    // Dictionary to contain the cache.
    static Dictionary<int, WeakReference> _cache;

    // Track the number of times an object is regenerated.
    int regenCount = 0;

    public Cache(int count)
    {
        _cache = new Dictionary<int, WeakReference>();

        // Add objects with a short weak reference to the cache.
       for (int i = 0; i < count; i++) {
            _cache.Add(i, new WeakReference(new Data(i), false));
        }
    }

    // Number of items in the cache.
    public int Count
    {
        get {  return _cache.Count; }
    }

    // Number of times an object needs to be regenerated.
    public int RegenerationCount
    {
        get { return regenCount; }
    }

    // Retrieve a data object from the cache.
    public Data this[int index]
    {
        get {
            Data d = _cache[index].Target as Data;
            if (d == null) {
                // If the object was reclaimed, generate a new one.
                Console.WriteLine("Regenerate object at {0}: Yes", index);
                d = new Data(index);
                _cache[index].Target = d;
                regenCount++;
            }
            else {
                // Object was obtained with the weak reference.
                Console.WriteLine("Regenerate object at {0}: No", index);
            }

            return d;
       }
    }
}

// This class creates byte arrays to simulate data.
public class Data
{
    private byte[] _data;
    private string _name;

    public Data(int size)
    {
        _data = new byte[size * 1024];
        _name = size.ToString();
    }

    // Simple property.
    public string Name
    {
        get { return _name; }
    }
}
// Example of the last lines of the output:
//
// ...
// Regenerate object at 36: Yes
// Regenerate object at 8: Yes
// Regenerate object at 21: Yes
// Regenerate object at 4: Yes
// Regenerate object at 38: No
// Regenerate object at 7: Yes
// Regenerate object at 2: Yes
// Regenerate object at 43: Yes
// Regenerate object at 38: No
// Cache size: 50, Regenerated: 94%
open System
open System.Collections.Generic

// This class creates byte arrays to simulate data.
type Data(size) =
    let _data = Array.zeroCreate<byte> (size * 1024)
    
    // Simple property.
    member _.Name = 
        string size

type Cache(count) =
    // Dictionary to contain the cache.
    static let mutable _cache = Dictionary<int, WeakReference>()

    // Track the number of times an object is regenerated.
    let mutable regenCount = 0

    do
        _cache <- Dictionary<int, WeakReference>()
        // Add objects with a short weak reference to the cache.
        for i = 0 to count - 1 do
            _cache.Add(i, WeakReference(Data i, false))

    // Number of items in the cache.
    member _.Count =
        _cache.Count

    // Number of times an object needs to be regenerated.
    member _.RegenerationCount =
        regenCount

    // Retrieve a data object from the cache.
    member _.Item
        with get (index) =
            match _cache[index].Target with
            | :? Data as d->
                // Object was obtained with the weak reference.
                printfn $"Regenerate object at {index}: No"
                d
            | _ ->
                // If the object was reclaimed, generate a new one.
                printfn $"Regenerate object at {index}: Yes"
                let d = Data index
                _cache[index].Target <- d
                regenCount <- regenCount + 1
                d 

// Create the cache.
let cacheSize = 50
let r = Random()
let c = Cache cacheSize

let mutable dataName = ""
GC.Collect 0

// Randomly access objects in the cache.
for _ = 0 to c.Count - 1 do
    let index = r.Next c.Count

    // Access the object by getting a property value.
    dataName <- c[index].Name

// Show results.
let regenPercent = double c.RegenerationCount / double c.Count
printfn $"Cache size: {c.Count}, Regenerated: {regenPercent:P2}%%"

// Example of the last lines of the output:
//
// ...
// Regenerate object at 36: Yes
// Regenerate object at 8: Yes
// Regenerate object at 21: Yes
// Regenerate object at 4: Yes
// Regenerate object at 38: No
// Regenerate object at 7: Yes
// Regenerate object at 2: Yes
// Regenerate object at 43: Yes
// Regenerate object at 38: No
// Cache size: 50, Regenerated: 94%
Imports System.Collections.Generic

Public Class Example
    Public Shared Sub Main()
        ' Create the cache. 
        Dim cacheSize As Integer = 50
        Dim r As Random = New Random()
        Dim c As Cache = New Cache(cacheSize)

        Dim DataName As String = "" 
        GC.Collect(0)
        
        ' Randomly access objects in the cache. 
        For ctr As Integer = 0 To C.Count - 1 
            Dim index As Integer = r.Next(c.Count)

            ' Access the object by getting a property value.
            DataName = c(index).Name
        Next 

        ' Show results. 
        Dim regenPercent As Double = c.RegenerationCount * 100 / c.Count
        Console.WriteLine("Cache size: {0}, Regenerated: {1}%", c.Count, regenPercent)
    End Sub 
End Class 

Public Class Cache
    ' Dictionary to contain the cache. 
    Private Shared _cache As Dictionary(Of Integer, WeakReference)

    ' Track the number of times an object is regenerated. 
    Dim regenCount As Integer = 0

    Public Sub New(ByVal count As Integer)
        _cache = New Dictionary(Of Integer, WeakReference)

        ' Add data objects with a short weak reference to the cache. 
        For ctr = 0 To count - 1
            _cache.Add(ctr, New WeakReference(New Data(ctr)))
        Next
    End Sub 

    ' Number of items in the cache. 
    Public ReadOnly Property Count() As Integer 
        Get 
            Return _cache.Count
        End Get 
    End Property 

    ' Number of times an object needs to be regenerated. 
    Public ReadOnly Property RegenerationCount() As Integer 
        Get 
            Return regenCount
        End Get 
    End Property 

    ' Retrieve a data object from the cache. 
    Default Public ReadOnly Property Item(ByVal index As Integer) As Data
        Get 
            Dim d As Data = TryCast(_cache(index).Target, Data)
            ' If the object was reclaimed, generate a new one.
            If d Is Nothing Then 
                Console.WriteLine("Regenerate object at {0}: Yes", index)
                d = New Data(index)
                _cache(index).Target = d
                regenCount += 1
           Else 
                ' Object was obtained with the weak reference.
                Console.WriteLine("Regenerate object at {0}: No", index.ToString())
            End If 
            Return d
        End Get 
    End Property 
End Class 

' Class that creates byte arrays to simulate data. 
Public Class Data
    Private _data() As Byte 
    Private _name As String 

    Public Sub New(ByVal size As Integer)
        _data = New Byte(((size * 1024)) - 1) {}
        _name = size.ToString
    End Sub 

    ' Simple property for accessing the object. 
    Public ReadOnly Property Name() As String 
        Get 
            Return _name
        End Get 
    End Property 
End Class 
' Example of the last lines of the output: 
' ... 
' Regenerate object at 36: Yes 
' Regenerate object at 8: Yes 
' Regenerate object at 21: Yes 
' Regenerate object at 4: Yes 
' Regenerate object at 38: No 
' Regenerate object at 7: Yes 
' Regenerate object at 2: Yes 
' Regenerate object at 43: Yes 
' Regenerate object at 38: No 
' Cache size: 50, Regenerated: 94%

Remarks

A weak reference allows the garbage collector to collect an object while still allowing an application to access the object. If you need the object, you can still obtain a strong reference to it and prevent it from being collected. For more information about how to use short and long weak references, see Weak References.

Constructors

WeakReference(Object, Boolean)

Initializes a new instance of the WeakReference class, referencing the specified object and using the specified resurrection tracking.

WeakReference(Object)

Initializes a new instance of the WeakReference class, referencing the specified object.

WeakReference(SerializationInfo, StreamingContext)
Obsolete.

Initializes a new instance of the WeakReference class, using deserialized data from the specified serialization and stream objects.

Properties

IsAlive

Gets an indication whether the object referenced by the current WeakReference object has been garbage collected.

Target

Gets or sets the object (the target) referenced by the current WeakReference object.

TrackResurrection

Gets an indication whether the object referenced by the current WeakReference object is tracked after it is finalized.

Methods

Equals(Object)

Determines whether the specified object is equal to the current object.

(Inherited from Object)
Finalize()

Discards the reference to the target represented by the current WeakReference object.

GetHashCode()

Serves as the default hash function.

(Inherited from Object)
GetObjectData(SerializationInfo, StreamingContext)
Obsolete.

Populates a SerializationInfo object with all the data needed to serialize the current WeakReference object.

GetType()

Gets the Type of the current instance.

(Inherited from Object)
MemberwiseClone()

Creates a shallow copy of the current Object.

(Inherited from Object)
ToString()

Returns a string that represents the current object.

(Inherited from Object)

Applies to

See also