Func<T1,T2,T3,T4,TResult> Delegate
Definition
Important
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Encapsulates a method that has four parameters and returns a value of the type specified by the TResult parameter.
generic <typename T1, typename T2, typename T3, typename T4, typename TResult>
public delegate TResult Func(T1 arg1, T2 arg2, T3 arg3, T4 arg4);public delegate TResult Func<in T1,in T2,in T3,in T4,out TResult>(T1 arg1, T2 arg2, T3 arg3, T4 arg4);public delegate TResult Func<T1,T2,T3,T4,TResult>(T1 arg1, T2 arg2, T3 arg3, T4 arg4);type Func<'T1, 'T2, 'T3, 'T4, 'Result> = delegate of 'T1 * 'T2 * 'T3 * 'T4 -> 'ResultPublic Delegate Function Func(Of In T1, In T2, In T3, In T4, Out TResult)(arg1 As T1, arg2 As T2, arg3 As T3, arg4 As T4) As TResult Public Delegate Function Func(Of T1, T2, T3, T4, TResult)(arg1 As T1, arg2 As T2, arg3 As T3, arg4 As T4) As TResult Type Parameters
- T1
The type of the first parameter of the method that this delegate encapsulates.
This type parameter is contravariant. That is, you can use either the type you specified or any type that is less derived. For more information about covariance and contravariance, see Covariance and Contravariance in Generics.- T2
The type of the second parameter of the method that this delegate encapsulates.
This type parameter is contravariant. That is, you can use either the type you specified or any type that is less derived. For more information about covariance and contravariance, see Covariance and Contravariance in Generics.- T3
The type of the third parameter of the method that this delegate encapsulates.
This type parameter is contravariant. That is, you can use either the type you specified or any type that is less derived. For more information about covariance and contravariance, see Covariance and Contravariance in Generics.- T4
The type of the fourth parameter of the method that this delegate encapsulates.
This type parameter is contravariant. That is, you can use either the type you specified or any type that is less derived. For more information about covariance and contravariance, see Covariance and Contravariance in Generics.- TResult
The type of the return value of the method that this delegate encapsulates.
This type parameter is covariant. That is, you can use either the type you specified or any type that is more derived. For more information about covariance and contravariance, see Covariance and Contravariance in Generics.Parameters
- arg1
- T1
The first parameter of the method that this delegate encapsulates.
- arg2
- T2
The second parameter of the method that this delegate encapsulates.
- arg3
- T3
The third parameter of the method that this delegate encapsulates.
- arg4
- T4
The fourth parameter of the method that this delegate encapsulates.
Return Value
The return value of the method that this delegate encapsulates.
Examples
The following example demonstrates how to declare and use a Func<T1,T2,TResult> delegate. This example declares a Func<T1,T2,TResult> variable and assigns it a lambda expression that takes a String value and an Int32 value as parameters. The lambda expression returns true if the length of the String parameter is equal to the value of the Int32 parameter. The delegate that encapsulates this method is subsequently used in a query to filter strings in an array of strings.
using System;
using System.Collections.Generic;
using System.Linq;
public class Func3Example
{
public static void Main()
{
Func<String, int, bool> predicate = (str, index) => str.Length == index;
String[] words = { "orange", "apple", "Article", "elephant", "star", "and" };
IEnumerable<String> aWords = words.Where(predicate).Select(str => str);
foreach (String word in aWords)
Console.WriteLine(word);
}
}
open System
open System.Linq
let predicate = Func<string, int, bool>(fun str index -> str.Length = index)
let words = [ "orange"; "apple"; "Article"; "elephant"; "star"; "and" ]
let aWords = words.Where predicate
for word in aWords do
printfn $"{word}"
Imports System.Collections.Generic
Imports System.Linq
Public Module Func3Example
Public Sub Main()
Dim predicate As Func(Of String, Integer, Boolean) = Function(str, index) str.Length = index
Dim words() As String = { "orange", "apple", "Article", "elephant", "star", "and" }
Dim aWords As IEnumerable(Of String) = words.Where(predicate)
For Each word As String In aWords
Console.WriteLine(word)
Next
End Sub
End Module
Remarks
You can use this delegate to represent a method that can be passed as a parameter without explicitly declaring a custom delegate. The encapsulated method must correspond to the method signature that is defined by this delegate. This means that the encapsulated method must have four parameters, each of which is passed to it by value, and that it must return a value.
Note
To reference a method that has four parameters and returns void (unit in F#) (or in Visual Basic, that is declared as a Sub rather than as a Function), use the generic Action<T1,T2,T3,T4> delegate instead.
When you use the Func<T1,T2,T3,T4,TResult> delegate, you do not have to explicitly define a delegate that encapsulates a method with four parameters. For example, the following code explicitly declares a generic delegate named Searcher and assigns a reference to the IndexOf method to its delegate instance.
using System;
delegate int Searcher(string searchString, int start, int count,
StringComparison type);
public class DelegateExample
{
public static void Main()
{
string title = "The House of the Seven Gables";
int position = 0;
Searcher finder = title.IndexOf;
do
{
int characters = title.Length - position;
position = finder("the", position, characters,
StringComparison.InvariantCultureIgnoreCase);
if (position >= 0)
{
position++;
Console.WriteLine("'The' found at position {0} in {1}.",
position, title);
}
} while (position > 0);
}
}
open System
type Searcher = delegate of (string * int * int * StringComparison) -> int
let title = "The House of the Seven Gables"
let finder = Searcher title.IndexOf
let mutable position = 0
while position > -1 do
let characters = title.Length - position
position <-
finder.Invoke("the", position, characters, StringComparison.InvariantCultureIgnoreCase)
if position >= 0 then
position <- position + 1
printfn $"'The' found at position {position} in {title}."
Delegate Function Searcher(searchString As String, _
start As Integer, _
count As Integer, _
type As StringComparison) As Integer
Module DelegateExample
Public Sub Main()
Dim title As String = "The House of the Seven Gables"
Dim position As Integer = 0
Dim finder As Searcher = AddressOf title.IndexOf
Do
Dim characters As Integer = title.Length - position
position = finder("the", position, characters, _
StringComparison.InvariantCultureIgnoreCase)
If position >= 0 Then
position += 1
Console.WriteLine("'The' found at position {0} in {1}.", _
position, title)
End If
Loop While position > 0
End Sub
End Module
The following example simplifies this code by instantiating the Func<T1,T2,T3,T4,TResult> delegate instead of explicitly defining a new delegate and assigning a named method to it.
using System;
public class DelegateExample
{
public static void Main()
{
string title = "The House of the Seven Gables";
int position = 0;
Func<string, int, int, StringComparison, int> finder = title.IndexOf;
do
{
int characters = title.Length - position;
position = finder("the", position, characters,
StringComparison.InvariantCultureIgnoreCase);
if (position >= 0)
{
position++;
Console.WriteLine("'The' found at position {0} in {1}.",
position, title);
}
} while (position > 0);
}
}
open System
let indexOf (s: string) s2 pos chars comparison =
s.IndexOf(s2, pos, chars, comparison)
let title = "The House of the Seven Gables"
let finder = Func<string, int, int, StringComparison, int>(indexOf title)
let mutable position = 0
while position > -1 do
let characters = title.Length - position
position <-
finder.Invoke("the", position, characters, StringComparison.InvariantCultureIgnoreCase)
if position >= 0 then
position <- position + 1
printfn $"'The' found at position {position} in {title}."
Module DelegateExample
Public Sub Main()
Dim title As String = "The House of the Seven Gables"
Dim position As Integer = 0
Dim finder As Func(Of String, Integer, Integer, StringComparison, Integer) _
= AddressOf title.IndexOf
Do
Dim characters As Integer = title.Length - position
position = finder("the", position, characters, _
StringComparison.InvariantCultureIgnoreCase)
If position >= 0 Then
position += 1
Console.WriteLine("'The' found at position {0} in {1}.", _
position, title)
End If
Loop While position > 0
End Sub
End Module
You can use the Func<T1,T2,T3,T4,TResult> delegate with anonymous methods in C#, as the following example illustrates. (For an introduction to anonymous methods, see Anonymous Methods.)
using System;
public class DelegateExample
{
public static void Main()
{
string title = "The House of the Seven Gables";
int position = 0;
Func<string, int, int, StringComparison, int> finder =
delegate(string s, int pos, int chars, StringComparison type)
{ return title.IndexOf(s, pos, chars, type); };
do
{
int characters = title.Length - position;
position = finder("the", position, characters,
StringComparison.InvariantCultureIgnoreCase);
if (position >= 0)
{
position++;
Console.WriteLine("'The' found at position {0} in {1}.",
position, title);
}
} while (position > 0);
}
}
You can also assign a lambda expression to a Func<T1,T2,TResult> delegate, as the following example illustrates. (For an introduction to lambda expressions, see Lambda Expressions (VB), Lambda Expressions (C#) and Lambda Expressions (F#).)
using System;
public class DelegateExample
{
public static void Main()
{
string title = "The House of the Seven Gables";
int position = 0;
Func<string, int, int, StringComparison, int> finder =
(s, pos, chars, type) => title.IndexOf(s, pos, chars, type);
do
{
int characters = title.Length - position;
position = finder("the", position, characters,
StringComparison.InvariantCultureIgnoreCase);
if (position >= 0)
{
position++;
Console.WriteLine("'The' found at position {0} in {1}.",
position, title);
}
} while (position > 0);
}
}
open System
let title = "The House of the Seven Gables"
let finder =
Func<string, int, int, StringComparison, int>(fun s pos chars typ -> title.IndexOf(s, pos, chars, typ))
let mutable position = 0
while position > -1 do
let characters = title.Length - position
position <- finder.Invoke("the", position, characters, StringComparison.InvariantCultureIgnoreCase)
if position >= 0 then
position <- position + 1
printfn $"'The' found at position {position} in {title}."
Module DelegateExample
Public Sub Main()
Dim title As String = "The House of the Seven Gables"
Dim position As Integer = 0
Dim finder As Func(Of String, Integer, Integer, StringComparison, Integer) _
= Function(s, pos, chars, type) _
title.IndexOf(s, pos, chars, type)
Do
Dim characters As Integer = title.Length - position
position = finder("the", position, characters, _
StringComparison.InvariantCultureIgnoreCase)
If position >= 0 Then
position += 1
Console.WriteLine("'The' found at position {0} in {1}.", _
position, title)
End If
Loop While position > 0
End Sub
End Module
The underlying type of a lambda expression is one of the generic Func delegates. This makes it possible to pass a lambda expression as a parameter without explicitly assigning it to a delegate. In particular, because many methods of types in the System.Linq namespace have Func parameters, you can pass these methods a lambda expression without explicitly instantiating a Func delegate.
Extension Methods
| GetMethodInfo(Delegate) |
Gets an object that represents the method represented by the specified delegate. |
