Question

This came to my mind after I learned the following from this question:

where T : struct

We, C# developers, all know the basics of C#. I mean declarations, conditionals, loops, operators, etc.

Some of us even mastered the stuff like Generics, anonymous types, lambdas, linq, ...

But what are the most hidden features or tricks of C# that even C# fans, addicts, experts barely know?

Here are the revealed features so far:

Keywords

yield by Michael Stum
var by Michael Stum
using() statement by kokos
readonly by kokos
as by Mike Stone
as / is by Ed Swangren
as / is (improved) by Rocketpants
default by deathofrats
global:: by pzycoman
using() blocks by AlexCuse
volatile by Jakub Šturc
extern alias by Jakub Šturc

Attributes

DefaultValueAttribute by Michael Stum
ObsoleteAttribute by DannySmurf
DebuggerDisplayAttribute by Stu
DebuggerBrowsable and DebuggerStepThrough by bdukes
ThreadStaticAttribute by marxidad
FlagsAttribute by Martin Clarke
ConditionalAttribute by AndrewBurns

Syntax

?? operator by kokos
number flaggings by Nick Berardi
where T:new by Lars Mæhlum
implicit generics by Keith
one-parameter lambdas by Keith
auto properties by Keith
namespace aliases by Keith
verbatim string literals with @ by Patrick
enum values by lfoust
@variablenames by marxidad
event operators by marxidad
format string brackets by Portman
property accessor accessibility modifiers by xanadont
ternary operator (?:) by JasonS
checked and unchecked operators by Binoj Antony
implicit and explicit operators by Flory

Language Features

Nullable types by Brad Barker
Currying by Brian Leahy
anonymous types by Keith
__makeref __reftype __refvalue by Judah Himango
object initializers by lomaxx
format strings by David in Dakota
Extension Methods by marxidad
partial methods by Jon Erickson
preprocessor directives by John Asbeck
DEBUG pre-processor directive by Robert Durgin
operator overloading by SefBkn
type inferrence by chakrit
boolean operators taken to next level by Rob Gough
pass value-type variable as interface without boxing by Roman Boiko
programmatically determine declared variable type by Roman Boiko
Static Constructors by Chris
Easier-on-the-eyes / condensed ORM-mapping using LINQ by roosteronacid

Visual Studio Features

select block of text in editor by Himadri
snippets by DannySmurf

Framework

TransactionScope by KiwiBastard
DependantTransaction by KiwiBastard
Nullable<T> by IainMH
Mutex by Diago
System.IO.Path by ageektrapped
WeakReference by Juan Manuel

Methods and Properties

String.IsNullOrEmpty() method by KiwiBastard
List.ForEach() method by KiwiBastard
BeginInvoke(), EndInvoke() methods by Will Dean
Nullable<T>.HasValue and Nullable<T>.Value properties by Rismo
GetValueOrDefault method by John Sheehan

Tips & Tricks

nice method for event handlers by Andreas H.R. Nilsson
uppercase comparisons by John
access anonymous types without reflection by dp
a quick way to lazily instantiate collection properties by Will
JavaScript-like anonymous inline-functions by roosteronacid

Other

netmodules by kokos
LINQBridge by Duncan Smart
Parallel Extensions by Joel Coehoorn

Answer 1

The following one is not hidden, but it's quite implicit. I don't know whether samples like the following one have been published here, and I can't see are there any benefits (probably there are none), but I'll try to show a "weird" code. The following sample simulates for statement via functors in C# (delegates / anonymous delegates [lambdas]) and closures. Other flow statements like if, if/else, while and do/whle are simulated as well, but I'm not sure for switch (perhaps, I'm too lazy :)). I've compacted the sample source code a little to make it more clear.

private static readonly Action EmptyAction = () => { };
private static readonly Func<bool> EmptyCondition = () => { return true; };

private sealed class BreakStatementException : Exception { }
private sealed class ContinueStatementException : Exception { }
private static void Break() { throw new BreakStatementException(); }
private static void Continue() { throw new ContinueStatementException(); }

private static void For(Action init, Func<bool> condition, Action postBlock, Action statement) {
    init = init ?? EmptyAction;
    condition = condition ?? EmptyCondition;
    postBlock = postBlock ?? EmptyAction;
    statement = statement ?? EmptyAction;
    for ( init(); condition(); postBlock() ) {
        try {
            statement();
        } catch ( BreakStatementException ) {
            break;
        } catch ( ContinueStatementException ) {
            continue;
        }
    }
}

private static void Main() {
    int i = 0; // avoiding error "Use of unassigned local variable 'i'" if not using `for` init block
    For(() => i = 0, () => i < 10, () => i++,
        () => {
            if ( i == 5 )
                Continue();
            Console.WriteLine(i);
        }
    );
}

If I'm not wrong, this approach is pretty relative to the functional programming practice. Am I right?

Answer 2

C# allows you to add property setter methods to concrete types that implement readonly interface properties even though the interface declaration itself has no property setter. For example:

public interface IReadOnlyFoo
{
   object SomeReadOnlyProperty { get; }
}

The concrete class looks like this:

internal class Foo : IReadOnlyFoo
{
   public object SomeReadOnlyProperty { get; internal set; }
}

What's interesting about this is that the Foo class is immutable if you cast it to the IReadOnlyFoo interface:

// Create a Foo instance
Foo foo = new Foo();

// This statement is legal
foo.SomeReadOnlyProperty = 12345;

// Make Foo read only
IReadOnlyFoo readOnlyFoo = foo;

// This statement won't compile
readOnlyFoo.SomeReadOnlyProperty = 54321;

Answer 3

Type-inference for factory methods

I don't know if this has been posted already (I scanned the first post, couldn't find it).

This is best shown with an example, assuming you have this class (to simulate a tuple), in in an attempt to demonstrate all the language features that make this possible I will go through it step by step.

public class Tuple<V1, V2> : Tuple
{
    public readonly V1 v1;
    public readonly V2 v2;

    public Tuple(V1 v1, V2 v2)
    {
      this.v1 = v1;
      this.v2 = v2;
    }
}

Everyone knows how to create an instance of it, such as:

Tuple<int, string> tup = new Tuple<int, string>(1, "Hello, World!");

Not exactly rocket science, now we can of course change the type declaration of the variable to var, like this:

var tup = new Tuple<int, string>(1, "Hello, World!");

Still well known, to digress a bit here's a static method with type parameters, which everyone should be familiar with:

public static void Create<T1, T2>()
{
    // stuff
}

Calling it is, again common knowledge, done like this:

Create<float, double>();

What most people don't know is that if the arguments to the generic method contains all the types it requires they can be inferred, for example:

public static void Create<T1, T2>(T1 a, T2 b)
{
    // stuff
}

These two calls are identical:

Create<float, string>(1.0f, "test");
Create(1.0f, "test");

Since T1 and T2 is inferred from the arguments you passed. Combining this knowledge with the var keyword, we can by adding a second static class with a static method, such as:

public abstract class Tuple
{
    public static Tuple<V1, V2> Create<V1, V2>(V1 v1, V2 v2)
    {
        return new Tuple<V1, V2>(v1, v2);
    }
}

Achieve this effect:

var tup = Tuple.Create(1, "Hello, World!");

This means that the types of the: variable "tup", the type-parameters of "Create" and the return value of "Create" are all inferred from the types you pass as arguments to Create

The full code looks something like this:

public abstract class Tuple
{
    public static Tuple<V1, V2> Create<V1, V2>(V1 v1, V2 v2)
    {
        return new Tuple<V1, V2>(v1, v2);
    }
}

public class Tuple<V1, V2> : Tuple
{
    public readonly V1 v1;
    public readonly V2 v2;

    public Tuple(V1 v1, V2 v2)
    {
        this.v1 = v1;
        this.v2 = v2;
    }
}

// Example usage:
var tup = Tuple.Create(1, "test");

Which gives you fully type inferred factory methods everywhere!

Answer 4

A couple I can think of:

[field: NonSerialized()]
public EventHandler event SomeEvent;

This prevents the event from being serialised. The 'field:' indicates that the attribute should be applied to the event's backing field.

Another little known feature is overriding the add/remove event handlers:

public event EventHandler SomeEvent
{
    add
    {
        // ...
    }

    remove
    {
        // ...
    }
}

Answer 5

Has anybody used "props"?

You type "prop" and then press [TAB] twice, it generates useful code for your properties and can speed your typing.

I know this works in VS 2005 (I use it) but I don´t know in previous versions.

Answer 6

In reading the book on development of the .NET framework. A good piece of advice is not to use bool to turn stuff on or off, but rather use ENums.

With ENums you give yourself some expandability without having to rewrite any code to add a new feature to a function.

Answer 7

System.Runtime.Remoting.Proxies.RealProxy

It enables Aspect Oriented Programming in C#, and you can also do a lot of other fancy stuff with it.

Answer 8

new modifier

Usage of the "new" modifier in C# is not exactly hidden but it's not often seen. The new modifier comes in handy when you need to "hide" base class members and not always override them. This means when you cast the derived class as the base class then the "hidden" method becomes visible and is called instead of the same method in the derived class.

It is easier to see in code:

public class BaseFoo
{
    virtual public void DoSomething()
    {
        Console.WriteLine("Foo");
    }
}

public class DerivedFoo : BaseFoo
{
    public new void DoSomething()
    {
        Console.WriteLine("Bar");
    }
}

public class DerivedBar : BaseFoo
{
    public override void DoSomething()
    {
        Console.WriteLine("FooBar");
    }
}

class Program
{
    static void Main(string[] args)
    {
        BaseFoo derivedBarAsBaseFoo = new DerivedBar();
        BaseFoo derivedFooAsBaseFoo = new DerivedFoo();

        DerivedFoo derivedFoo = new DerivedFoo();

        derivedFooAsBaseFoo.DoSomething(); //Prints "Foo" when you might expect "Bar"
        derivedBarAsBaseFoo.DoSomething(); //Prints "FooBar"

        derivedFoo.DoSomething(); //Prints "Bar"
    }
}

[Ed: Do I get extra points for puns? Sorry, couldn't be helped.]

Answer 9

Instead of using int.TryParse() or Convert.ToInt32(), I like having a static integer parsing function that returns null when it can't parse. Then I can use ?? and the ternary operator together to more clearly ensure my declaration and initialization are all done on one line in a easy-to-understand way.

public static class Parser {
    public static int? ParseInt(string s) {
        int result;
        bool parsed = int.TryParse(s, out result);
        if (parsed) return result;
        else return null;
    }
    // ...
}

This is also good to avoid duplicating the left side of an assignment, but even better to avoid duplicating long calls on the right side of an assignment, such as a database calls in the following example. Instead of ugly if-then trees (which I run into often):

int x = 0;
YourDatabaseResultSet data = new YourDatabaseResultSet();
if (cond1)
    if (int.TryParse(x_input, x)){
        data = YourDatabaseAccessMethod("my_proc_name", 2, x);
    }
    else{
        x = -1;
        // do something to report "Can't Parse"    
    }
}
else {
    x = y;
    data = YourDatabaseAccessMethod("my_proc_name", 
       new SqlParameter("@param1", 2),
       new SqlParameter("@param2", x));
}

You can do:

int x = cond1 ? (Parser.ParseInt(x_input) ?? -1) : y;
if (x >= 0)  data = YourDatabaseAccessMethod("my_proc_name", 
    new SqlParameter("@param1", 2),
    new SqlParameter("@param2", x));

Much cleaner and easier to understand

Answer 10

Object.ReferenceEquals Method

Determines whether the specified Object instances are the same instance.

Parameters:

• objA: System.Object - The first Object to compare.
• objB: System.Object - The second Object to compare.

Example:

 object o = null;
 object p = null;
 object q = new Object();

 Console.WriteLine(Object.ReferenceEquals(o, p));
 p = q;
 Console.WriteLine(Object.ReferenceEquals(p, q));
 Console.WriteLine(Object.ReferenceEquals(o, p));

Difference to "==" and ".Equals":

Basically, Equals() tests of object A has the same content as object B.

The method System.Object.ReferenceEquals() always compares references. Although a class can provide its own behavior for the equality operator (below), that re-defined operator isn't invoked if the operator is called via a reference to System.Object.

For strings there isn't really a difference, because both == and Equals have been overriden to compare the content of the string.

See also this answer to another question ("How do I check for nulls in an ‘==’ operator overload without infinite recursion?").

Answer 11

@Andreas H.R. Nilsson regarding foreach: It does not use 'duck typing', as duck typing IMO refers to a runtime check. It uses structural type checking (as opposed to nominal) at compile time to check for the required method in the type. (Sorry for the new post, I don't have enough points to post comments directly to posts yet.)

Answer 12

(I just used this one) Set a field null and return it without an intermediate variable:

try
{
    return _field;
}
finally
{
    _field = null;
}

Answer 13

Here's one I discovered recently which has been useful:

Microsoft.VisualBasic.Logging.FileLogTraceListener

MSDN Link

This is a TraceListener implementation which has a lot of features, such as automatic log file roll over, which I previously would use a custom logging framework for. The nice thing is that it is a core part of .NET and is integrated with the Trace framework, so its easy to pick up and use immediately.

This is "hidden" because its in the Microsoft.VisualBasic assembly... but you can use it from C# as well.

Answer 14

The usage of the default keyword in generic code to return the default value for a type.

public class GenericList<T>
{
    private class Node
    {
        //...

        public Node Next;
        public T Data;
    }

    private Node head;

    //...

    public T GetNext()
    {
        T temp = default(T);

        Node current = head;
        if (current != null)
        {
            temp = current.Data;
            current = current.Next;
        }
        return temp;
    }
}

Another example here

Answer 15

Zero parameter Lambdas

()=>Console.ReadLine()

Answer 16

One that I just learned recently is that you can still call methods on a nullable value....

It turns out what when you have a nullable value:

decimal? MyValue = null;

where you might think you would have to write:

MyValue == null ? null : MyValue .ToString()

you can instead write:

MyValue.ToString()

I've been aware that I could call MyValue.HasValue and MyValue.Value...but it didn't fully click that I could call ToString().

Answer 17

@lainMH,

Nullable booleans are useful when retrieving values from a database that are nullable and when putting values back in. Sometimes you want to know the field has not been set.

Answer 18

Thought about @dp AnonCast and decided to try it out a bit. Here's what I come up with that might be useful to some:

// using the concepts of dp's AnonCast
static Func<T> TypeCurry<T>(Func<object> f, T type)
{
    return () => (T)f();
}

And here's how it might be used:

static void Main(string[] args)
{

    var getRandomObjectX = TypeCurry(GetRandomObject,
        new { Name = default(string), Badges = default(int) });

    do {

        var obj = getRandomObjectX();

        Console.WriteLine("Name : {0} Badges : {1}",
            obj.Name,
            obj.Badges);

    } while (Console.ReadKey().Key != ConsoleKey.Escape);

}

static Random r = new Random();
static object GetRandomObject()
{
    return new {
        Name = Guid.NewGuid().ToString().Substring(0, 4),
        Badges = r.Next(0, 100)
    };
}

Answer 19

I like to use the using directive to rename some classes for easy reading like this:

// defines a descriptive name for a complexed data type
using MyDomainClassList = System.Collections.Generic.List<
  MyProjectNameSpace.MyDomainClass>;

....


MyDomainClassList myList = new MyDomainClassList();
/* instead of 
List<MyDomainClass> myList = new List<MyDomainClass>();
*/

This is also very handy for code maintenance. If you need to change the class name, there is only one place you need to change. Another example:

using FloatValue  = float; // you only need to change it once to decimal, double...

....
FloatValue val1;
...

Answer 20

You can create delegates from extension methods as if they were regular methods, currying the this parameter. For example,

static class FunnyExtension {
	public static string Double(this string str) { return str + str; }
	public static int Double(this int num) { return num + num; }
}


Func<string> aaMaker = "a".Double;
Func<string, string> doubler = FunnyExtension.Double;

Console.WriteLine(aaMaker());		//Prints "aa"
Console.WriteLine(doubler("b"));	//Prints "bb"

Note that this won't work on extension methods that extend a value type; see this question.

Answer 21

Pointers in C#.

They can be used to do in-place string manipulation. This is an unsafe feature so the unsafe keyword is used to mark the region of unsafe code. Also note how the fixed keyword is used to indicate that the memory pointed to is pinned and cannot be moved by the GC. This is essential a pointers point to memory addresses and the GC can move the memory to different address otherwise resulting in an invalid pointer.

	string str = "some string";
	Console.WriteLine(str);
	unsafe
	{
		fixed(char *s = str)
		{
			char *c = s;
			while(*c != '\0')
			{
				*c = Char.ToUpper(*c++);					
			}
		}
	}
	Console.WriteLine(str);

I wouldn't ever do it but just for the sake of this question to demonstrate this feature.

Answer 22

I have often come across the need to have a Generic parameter-object persisted into the viewstate in a base class.

public abstract class BaseListControl<ListType,KeyType,ParameterType>
                 : UserControl 
                 where ListType : BaseListType
                 && ParameterType : BaseParameterType, new
{

    private const string viewStateFilterKey = "FilterKey";

    protected ParameterType Filters
    {
        get
        {
            if (ViewState[viewStateFilterKey] == null)
                ViewState[viewStateFilterKey]= new ParameterType();

            return ViewState[viewStateFilterKey] as ParameterType;
        }
        set
        {
            ViewState[viewStateFilterKey] = value;
        }
    }

}

Usage:

private void SomeEventHappened(object sender, EventArgs e)
{
    Filters.SomeValue = SomeControl.SelectedValue;
}

private void TimeToFetchSomeData()
{
    GridView.DataSource = Repository.GetList(Filters);
}

This little trick with the "where ParameterType : BaseParameterType, new" is what makes it really work.
With this property in my baseclass, I can automate handling of paging, setting filter values to filter a gridview, make sorting really easy, etc etc.

Really just saying that generics can be an enormously powerful beast in the wrong hands.

Answer 23

Dictionary initializers are always useful for quick hacks and unit tests where you need to hardcode some data.

var dict = new Dictionary<int, string> { { 10, "Hello" }, { 20, "World" } };

Answer 24

Easier-on-the-eyes / condensed ORM-mapping using LINQ

Consider this table:

[MessageId] INT,
[MessageText] NVARCHAR(MAX)
[MessageDate] DATETIME

... And this structure:

struct Message
{
    Int32 Id;
    String Text;
    DateTime Date;
}

Instead of doing something along the lines of:

List<Message> messages = new List<Message>();

foreach (row in DataTable.Rows)
{
    var message = new Message
    {
        Id = Convert.ToInt32(row["MessageId"]),
        Text = Convert.ToString(row["MessageText"]),
        Date = Convert.ToDateTime(row["MessageDate"])
    };

    messages.Add(message);
}

You can use LINQ and do the same thing with fewer lines of code, and in my opinion; more style. Like so:

var messages = DataTable.AsEnumerable().Select(r => new Message
{
    Id = Convert.ToInt32(r["MessageId"]),
    Text = Convert.ToString(r["MessageText"]),
    Date = Convert.ToDateTime(r["MessageDate"])
}).ToList();

This approach can be nested, just like loops can.

Answer 25

Currying using

FastFunc<T,U>

Answer 26

@Horsey: You're right, I thought of that after I posted. I am no pro here and am still learning, so I do make the occasional bad post here and there.

@Mike: The as keyword is great, and also lends itself to the use of the "is" keyword:

 MyClass c;
 if (obj is MyClass)
      c = obj as MyClass

I'm sure that this is no secret, but I did not find this for at least 6 months into learning C#.

Answer 27

Reflection Emit and Expression trees come to mind...

Don't miss Jeffrey Richter's CLR via C# and Jon Skeet's

See here for some resources:

http://www.codeproject.com/KB/trace/releasemodebreakpoint.aspx

http://www.codeproject.com/KB/dotnet/Creating_Dynamic_Types.aspx

http://www.codeproject.com/KB/cs/lambdaexpressions.aspx

Answer 28

TryParse method for each primitive type is great when validating user input.

double doubleValue Double.TryParse(myDataRow("myColumn"), doubleValue)

Answer 29

The #region {string} and #endregion pair is very neat for grouping code (outlining).

#region Using statements
using System;
using System.IO;
using ....;
using ....;
#endregion

The code block can be compressed to a single describing line of text. Works inside functions aswell.

Answer 30

Literals can be used as variables of that type. eg.

Console.WriteLine(5.ToString());
Console.WriteLine(5M.GetType());   // Returns "System.Decimal"
Console.WriteLine("This is a string!!!".Replace("!!", "!"));

Just a bit of trivia...

There's quite a few things people haven't mentioned, but they have mostly to do with unsafe constructs. Here's one that can be used by "regular" code though:

The checked/unchecked keywords:

public static int UncheckedAddition(int a, int b)
{
    unchecked { return a + b; }
}

public static int CheckedAddition(int a, int b)
{
    checked { return a + b; } // or "return checked(a + b)";
}

public static void Main() 
{
    Console.WriteLine("Unchecked: " + UncheckedAddition(Int32.MaxValue, + 1));  // "Wraps around"
    Console.WriteLine("Checked: " + CheckedAddition(Int32.MaxValue, + 1));  // Throws an Overflow exception
    Console.ReadLine();
}