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

DefaultValue 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

Visual Studio Features

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

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();
}

Answer 2

Some concurrency utilities in the BCL might qualify as hidden features.

Things like System.Threading.Monitor are used internally by the lock keyword; clearly in C# the lock keyword is preferrable, but sometimes it pays to know how things are done at a lower level; I had to lock in C++/CLI, so I encased a block of code with calls to Monitor.Enter() and Monitor.Exit().

Answer 3

Static constructors.

Instances:

public class Example
{
    static Example()
    {
        // Code to execute during type initialization
    }

    public Example()
    {
        // Code to execute during object initialization
    }
}

Static classes:

public static class Example
{
    static Example()
    {
        // Code to execute during type initialization
    }
}

MSND says:

A static constructor is used to initialize any static data, or to perform a particular action that needs performed once only. It is called automatically before the first instance is created or any static members are referenced.

For example:

public class MyWebService
{
    public static DateTime StartTime;

    static MyWebService()
    {
        MyWebService.StartTime = DateTime.Now;
    }

    public TimeSpan Uptime
    {
        get { return DateTime.Now - MyWebService.StartTime; }
    }
}

But, you could also just as easily have done:

public class MyWebService
{
    public static DateTime StartTime = DateTime.Now;

    public TimeSpan Uptime
    {
        get { return DateTime.Now - MyWebService.StartTime; }
    }
}

So you'll be hard-pressed to find any instance when you actually need to use a static constructor.

MSDN offers useful notes on static constructors:

• A static constructor does not take access modifiers or have parameters.

• A static constructor is called automatically to initialize the class before the first instance is created
  or any static members are referenced.

• A static constructor cannot be called directly.

• The user has no control on when the static constructor is executed in the program.

• A typical use of static constructors is when the class is using a log file and the constructor is used to write
  entries to this file.

• Static constructors are also useful when creating wrapper classes for
  unmanaged code, when the constructor
  can call the LoadLibrary method.

• If a static constructor throws an exception, the runtime will not
  invoke it a second time, and the type will remain uninitialized for the
  lifetime of the application domain in which your program is running.

The most important note is that if an error occurs in the static constructor, a TypeIntializationException is thrown and you cannot drill down to the offending line of code. Instead, you have to examine the TypeInitializationException's InnerException member, which is the specific cause.

Answer 4

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 5

Falling through switch-cases can be achieved by having no code in a case (see case 0), or using the special goto case (see case 1) or goto default (see case 2) forms:

switch (/*...*/) {
    case 0: // shares the exact same code as case 1
    case 1:
        // do something
        goto case 2;
    case 2:
        // do something else
        goto default;
    default:
        // do something entirely different
        break;
}

Answer 6

Don't forget about goto.

Answer 7

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 8

Aliased generics:

using ASimpleName = Dictionary<string, Dictionary<string, List<string>>>;

It allows you to use ASimpleName, instead of Dictionary<string, Dictionary<string, List<string>>>.

Use it when you would use the same generic big long complex thing in a lot of places.

Answer 9

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 10

1. I can't comment yet, but note that by default VS2008 automatically steps over properties, so the DebuggerStepThrough attribute is no longer needed in that case.

2. Also, I haven't noticed anyone showing how to declare a parameter-less lambda (usefull for implementing Action<>)

   () => DoSomething(x);

   You should also read up on closures - I'm not clever enough to explain them properly. But basically it means that the compiler does clever stuff so that the x in that line of code will still work even if it goes 'out of scope' after creating the lambda.

3. I also discovered recently that you can pretend to ignore a lambda parameter:

   (e, _) => DoSomething(e)

   It's not really ignoring it, it's just that _ is a valid identifier. So you couldn't ignore both of the parameters like that, but I think it is a kind of neat way to indicate that we don't care about that parameter (typically the EventArgs which is .Empty).

Answer 11

I couldn't see this looking above - one this I didn't realise you could do until recently is call one constructor from another:

class Example
{
    public Example(int value1)
        : this(value1, "Default Value")
    {
    }

    public Example(int value1, string value2)
    {
        m_Value1 = value1;
        m_value2 = value2;
    }

    int m_Value1;
    string m_value2;
}

Answer 12

The volatile keyword to tell to the compiler that field can be modified by multiple threads concurrently.

Answer 13

My favorite trick is using the null coalesce operator and parentheses to automagically instantiate collections for me.

private IList<Foo> _foo;

public IList<Foo> ListOfFoo 
    { get { return _foo ?? (_foo = new List<Foo>()); } }

Answer 14

I think one of the most under-appreciated and lesser-known features of C# (3.5) are Expression Trees, especially when combined with Generics and Lambdas. This is an approach to API creation that newer libraries like NInject and Moq are using.

For example, let's say that I want to register a method with an API and that API needs to get the method name

Given this class:

public class MyClass
{
     public void SomeMethod() { /* Do Something */ }
}

Before, it was very common to see developers do this with strings and types (or something else largely string-based):

RegisterMethod(typeof(MyClass), "SomeMethod");

Well, that sucks because of the lack of strong-typing. What if I rename "SomeMethod"? Now, in 3.5 however, I can do this in a strongly-typed fashion:

RegisterMethod<MyClass>(cl => cl.SomeMethod());

In which the RegisterMethod class uses Expression> like this:

void RegisterMethod<T>(Expression<Action<T>> action) where T : class
{
    var expression = (action.Body as MethodCallExpression);

    if (expression != null)
    {
        // TODO: Register method
        Console.WriteLine(expression.Method.Name);
    }
}

This is one big reason that I'm in love with Lambdas and Expression Trees right now.

Answer 15

A couple things I like:

-If you create an interface similar to:

 public interface SomeObject<T> where T : SomeObject<T>, new()

you force anything that inherits from this interface to contain a parameterless constructor... very useful for a couple things I've run across.

-Using anonymous types to create a useful object on the fly

var myAwesomeObject = new {Name="Foo", Size=10};

-Finally, many Java developers are familiar with syntax like

public synchronized void MySynchronizedMethod(){}

however, in C# this is not valid syntax. The workaround is a method header:

 [MethodImpl(MethodImplOptions.Synchronized)]
 public void MySynchronizedMethod(){}

Answer 16

Saw a mention of List.ForEach above; 2.0 introduced a bevy of predicate-based collection operations - Find, FindAll, Exists, etc. Coupled with anonymous delegates you can almost achieve the simplicity of 3.5's lambda expressions.

Answer 17

Not a C# specific thing, but I am a ternary operations junkie.

Instead of

if (boolean Condition)
{
    //Do Function
}
else
{
    //Do something else
}

you can use a succinct

booleanCondtion ? true operation : false operation;

e.g.

Instead of

int value = param;
if (doubleValue)
{
    value *= 2;
}
else
{
    value *= 3;
}

you can type

int value = param * (tripleValue ? 3 : 2);

It does help write succinct code, but nesting the damn things can be nasty, and they can be used for evil, but I love the little suckers nonetheless

Answer 18

I like the keyword continue.

If you hit a condition in a loop and don't want to do anything but advance the loop just stick in "continue;".

E.g.:

foreach(object o in ACollection)
{
  if(NotInterested)
     continue;
}

Answer 19

I just found out about this one today -- and I've been working with C# for 5 years!

It's the namespace alias qualifier:

extern alias YourAliasHere

You can use it to load multiple versions of the same type. This can be useful in maintenance or upgrade scenarios where you have an updated version of your type that won't work in some old code, but you need to upgrade it to the new version. Slap on a namespace alias qualifier, and the compiler will let you have both types in your code.

Answer 20

InternalsVisibleTo attribute is one that is not that well known, but can come in increadibly handy in certain circumstances. It basically allows another assembly to be able to access "internal" elements of the defining assembly.

Answer 21

@David in Dakota:

Console.WriteLine( "-".PadRight( 21, '-' ) );

I used to do this, until I discovered that the String class has a constructor that allows you to do the same thing in a cleaner way:

new String('-',22);

Answer 22

@Robbie Rocketpants

"but my instincts tell me that this would cut a maximum of two type casts operations down to a maximum of one."

If you do the cast as you were suggesting in example 1 (using is & as), it results in 2 calls to the "is" operator. Because when you do "c = obj as MyClass", first it calls "is" behind the scenes, then if it fails that it simply returns null.

If you do the cast as you were suggesting in example 2,

c = (MyClass)obj

Then this actually performs the "is" operation again, then if it fails that check,it throws an exception (InvalidCastException).

So, if you wanted to do a lightweight dynamic cast, it's best to do the 3rd example you provided:

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

if (c != null)
{
}

vs

MyClass c = obj as MyClass;

if (c != null)
{
}

You can see which is quicker, more consise and clearer.

Answer 23

There are some really hidden keywords and features in C# related to the TypedReference undocumented class. The following keywords are undocumented:

• **__makeref
• __reftype
• __refvalue
• arglist

Examples of use:

// Create a typed reference
int i = 1;
TypedReference tr1 = __makeref(i);
// Get the type of a typed reference
Type t = __reftype(tr1);
// Get the value of a typed referece
int j = __refvalue(tr1, int); 
// Create a method that accepts and arbitrary number of typed references
void SomeMethod(__arglist) { ...
// Call the method
int x = 1;
string y = "Foo";
Object o = new Object();
SomeMethod(__arglist(x,y,o));
// And finally iterate over method parameters
void SomeMethod(__arglist) {
    ArgIterator ai = new ArgIterator(__arglist);
while(ai.GetRemainingCount() >0)
{
	  TypedReference tr = ai.GetNextArg();
	  Console.WriteLine(TypedReference.ToObject(tr));
}}

Answer 24

Foreach uses Duck Typing

Paraphrasing, or shamelessly stealing from Krzysztof Cwalinas blog on this. More interesting trivia than anything.

For your object to support foreach, you don't have to implement IEnumerable. I.e. this is not a constraint and it isn't checked by the compiler. What's checked is that

• Your object provide a public method GetEnumerator that
  • takes no parameters
  • return a type that has two members
    1. a parameterless method MoveNext that returns a boolean
    2. a property Current with a getter that returns an Object

For example,

class Foo
{
    public Bar GetEnumerator() { return new Bar(); }

    public struct Bar
    {
        public bool MoveNext()
        {
            return false;
        }

        public object Current
        {
            get { return null; }
        }
    }
}

// the following complies just fine:
Foo f = new Foo();
foreach (object o in f)
{
    Console.WriteLine("Krzysztof Cwalina's da man!");
}

Answer 25

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

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

Answer 26

PreviousPage property:

"The System.Web.UI.Page representing the page that transferred control to the current page."

It is very useful.

Answer 27

The extern alias keyword to reference two versions of assemblies that have the same fully-qualified type names.

Answer 28

Nesting Using Statements

Usually we do it like this:

StringBuilder sb = new StringBuilder();
using (StringWriter sw = new StringWriter()) {
    using (IndentedTextWriter itw = new IndentedTextWriter(sw)) {
        ... 
    }
}

But we can do it this way:

StringBuilder sb = new StringBuilder();
using (StringWriter sw = new StringWriter())
using (IndentedTextWriter itw = new IndentedTextWriter(sw)) {
    ... 
}

Answer 29

Environment.NewLine

for system independent newlines.

Answer 30

ConditionalAttribute

Allows you to tell the compiler to omit the call to the method marked with the attribute under certain conditions (#define).

The fact that the method call is omitted also means that its parameters are not evaluated. This is very handy and it's what allows you to call expensive validation functions in Debug.Assert() and not worry about them slowing down your release build.