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
pass value-type variable as interface without boxing by Roman Boiko
programmatically determine declared variable type by Roman Boiko

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

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 2

On the basis that this thread should be entitled "things you didn't know about C# until recently despite thinking you already knew everything", my personal feature is asynchronous delegates.

Until I read Jeff Richter's C#/CLR book (excellent book, everyone doing .NET should read it) I didn't know that you could call any delegate using BeginInvoke / EndInvoke. I tend to do a lot of ThreadPool.QueueUserWorkItem calls (which I guess is much like what the delegate BeginInvoke is doing internally), but the addition of a standardised join/rendezvous pattern may be really useful sometimes.

Answer 3

The C# ?? null coalescing operator -

Not really hidden, but rarely used. Probably because a lot of developers run a mile when they see the conditional ? operator, so they runt two when they see this one. Used:

string mystring = foo ?? "foo was null"

rather than

string mystring;
if (foo==null)
    mystring = "foo was null";
else
    mystring = foo;

Answer 4

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 5

The params keyword, i.e.

public void DoSomething(params string[] theStrings)
{
  foreach(string s in theStrings)
  {
    // Something with the Strings…
  }
}

Called like

DoSomething(“The”, “cat”, “sat”, “on”, “the” ,”mat”);

Answer 6

The #if DEBUG pre-processor directive. It is Useful for testing and debugging (though I usually prefer to go the unit testing route).

string customerName = null;
#if DEBUG
  customerName = "Bob"
#endif

It will only execute code block if Visual Studio is set to compile in 'Debug' mode. Otherwise the code block will be ignored by the compiler (and grayed out in Visual Studio).

Answer 7

Full access to the call stack:

public static void Main()
{
  StackTrace stackTrace = new StackTrace();           // get call stack
  StackFrame[] stackFrames = stackTrace.GetFrames();  // get method calls (frames)

  // write call stack method names
  foreach (StackFrame stackFrame in stackFrames)
  {
    Console.WriteLine(stackFrame.GetMethod().Name);   // write method name
  }
}

So, if you'll take the first one - you know what function you are in. If you're creating a helper tracing function - take one before the last one - you'll know your caller.

Answer 8

Several people have mentioned using blocks, but I think they are much more useful than people have realised. Think of them as the poor man's AOP tool. I have a host of simple objects that capture state in the constructor and then restore it in the Dispose() method. That allows me to wrap a piece of functionality in a using block and be sure that the state is restore at the end. For example:

using(new CursorState(this, BusyCursor));
{
    // Do stuff
}

CursorState captures the current cursor being used by form, then sets the form to use the cursor supplied. At the end it restores the original cursor. I do loads of things like this, for example capturing the selections and current row on a grid before refreshing and so on.

Answer 9

Use "throw;" instead of "throw ex;" to preserve stack trace

If re-throwing an exception without adding additional information, use "throw" instead of "throw ex". An empty "throw" statement in a catch block will emit specific IL that re-throws the exception while preserving the original stack trace. "throw ex" loses the stack trace to the original source of the exception.

Answer 10

Don't forget about goto.

Answer 11

There's also the ThreadStaticAttribute to make a static field unique per thread, so you can have strongly typed thread-local storage.

Even if extension methods aren't that secret (LINQ is based on them), it may not be so obvious as to how useful and more readable they can be for utility helper methods:

//for adding multiple elements to a collection that doesn't have AddRange
//e.g., collection.Add(item1, item2, itemN);
static void Add<T>(this ICollection<T> coll, params T[] items)
 { foreach (var item in items) coll.Add(item);
 }

//like string.Format() but with custom string representation of arguments
//e.g., "{0} {1} {2}".Format<Custom>(c=>c.Name,"string",new object(),new Custom())
//      result: "string {System.Object} Custom1Name"
static string Format<T>(this string format, Func<T,object> select, params object[] args)
 { for(int i=0; i < args.Length; ++i)
    { var x = args[i] as T;
      if (x != null) args[i] = select(x);
    }
   return string.Format(format, args);
 }

Answer 12

I love using the @ character for SQL queries. It keeps the sql nice and formatted and without having to surround each line with a string delimiter.

string sql = @"SELECT firstname, lastname, email
               FROM users
               WHERE username = @username AND password = @password";

Answer 13

C# 3.0's LINQ query comprehensions are full-blown monadic comprehensions a la Haskell (in fact they were designed by one of Haskell's designers). They will work for any generic type that follows the "LINQ pattern" and allows you to write in a pure monadic functional style, which means that all of your variables are immutable (as if the only variables you used were IDisposables and IEnumerables in using and foreach statements). This is helpful for keeping variable declarations close to where they're used and making sure that all side-effects are explicitly declared, if there are any at all.

 interface IFoo<T>
  { T Bar {get;}
  }

 class MyFoo<T> : IFoo<T> 
  { public MyFoo(T t) {Bar = t;}
    public T Bar {get; private set;} 
  }

 static class Foo 
  { public static IFoo<T> ToFoo<T>(this T t) {return new MyFoo<T>(t);}

    public static void Do<T>(this T t, Action<T> a) { a(t);}

    public static IFoo<U> Select<T,U>(this IFoo<T> foo, Func<T,U> f) 
     { return f(foo.Bar).ToFoo();
     }
  }

 /* ... */

 using (var file = File.OpenRead("objc.h"))
 { var x = from f in file.ToFoo()
           let s = new Scanner(f)
           let p = new Parser {scanner = s}
           select p.Parse();

   x.Do(p => 
    { /* drop into imperative code to handle file 
         in Foo monad if necessary */      
    });

 }

Answer 14

One great class I like is System.Xml.XmlConvert which can be used to read values from xml tag. Especially, if I am reading a boolean value from xml attribute or element, I use

bool myFlag  = System.Xml.XmlConvert.ToBoolean(myAttribute.Value);

Note: since boolean type in xml accepts 1 and 0 in addition to "true" and "false" as valid values, using string comparison in this case is error-prone.

Answer 15

Ability to use LINQ Expressions to perform strongly-typed reflection:

static void Main(string[] args)
{
  var domain = "matrix";
  Check(() => domain);
  Console.ReadLine();
}

static void Check<T>(Expression<Func<T>> expr)
{
  var body = ((MemberExpression)expr.Body);
  Console.WriteLine("Name is: {0}", body.Member.Name);
  Console.WriteLine("Value is: {0}", ((FieldInfo)body.Member)
   .GetValue(((ConstantExpression)body.Expression).Value));
}

// output:
// Name is: 'domain'
// Value is: 'matrix'

More details are available at How to Find Out Variable or Parameter Name in C#?

Answer 16

My favorite attribute: InternalsVisibleTo

At assembly level you can declare that another assembly can see your internals. For testing purposes this is absolutely wonderful.

Stick this in your AssemblyInfo.cs or equivalent and your test assembly get full access to all the internal stuff that requires testing.

[assembly: InternalsVisibleTo("MyLibrary.Test, PublicKey=0024...5c042cb")]

As you can see, the test assembly must have a strong name to gain the trust of the assembly under test.

Available in .Net Framework 2.0+, Compact Framework 2.0+ and XNA Framework 1.0+.

Answer 17

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.

Answer 18

Two of my personal favourites, which I see rarely used:

1. Snippets (particularly for properties, which was made even better for 2008)
2. The ObsoleteAttribute

Answer 19

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 20

You can use any Unicode character in C# names, for example:

public class MyClass
{
    public string Hårføner()
    {
        return "Yes, it works!";
    }
}

You can even use Unicode escapes. This one is equivalent to the above:

public class MyClass
{
    public string H\u00e5rføner()
    {
        return "Yes, it (still) works!";
    }
}

Answer 21

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 22

What about using this:

#if DEBUG
            Console.Write("Debugging");
#else
            Console.Write("Final");
#endif

When you have your solution compiled with DEBUG defined it will output "Debugging".

If your compile is set to Release it will write "Final".

Answer 23

Not sure if this one got mentioned yet but the ThreadStatic attribute is a realy useful one. This makes a static field static just for the current thread.

[ThreadStatic]
private static int _ThreadStaticInteger;

You should not include an initializer because it only get executed once for the entire application, you're better off making the field nullable and checking if the value is null before you use it.

And one more thing for ASP.NET applications threads are reused so if you modify the value it could end up being used for another page request.

Still I have found this useful on several occasions. For example in creating a custom transaction class that:

using (DbTransaction tran = new DbTransaction())
{
    DoQuery("...");
    DoQuery("...");    
}

The DbTransaction constructor sets a ThreadStatic field to its self and resets it to null in the dispose method. DoQuery checks the static field and if != null uses the current transaction if not it defaults to something else. We avoid having to pass the transaction to each method plus it makes it easy to wrap other methods that were not originaly meant to be used with transaction inside a transaction ...

Just one use :)

Answer 24

I love the fact that I can use LINQ to objects on plain old .NET 2.0 (i.e. without requiring .NET 3.5 to be installed everywhere). All you need is an implementation of all the query operator Extension methods - see LINQBridge

Answer 25

I'm late to this party, so my first choices are already taken. But I didn't see anyone mention this gem yet:

Parallel Extensions to the .Net Framework

It has things like replace with Parallel.For or foreach with Parallel.ForEach

Answer 26

true and false operators are really weird.

More comprehensive example can be found here.

Edit: There is related SO question What’s the false operator in C# good for?

Answer 27

Something I missed for a long time: you can compare strings with

"string".equals("String", StringComparison.InvariantCultureIgnoreCase)

instead of doing:

"string".ToLower() == "String".ToLower();

Answer 28

You can use generics to check (compile time) if a method argument implements two interfaces:

interface IPropA 
{
    string PropA { get; set; } 
}

interface IPropB 
{
    string PropB { get; set; }
}

class TestClass 
{
    void DoSomething<T>(T t) where T : IPropA, IPropB 
    {
        MessageBox.Show(t.PropA);
        MessageBox.Show(t.PropB);
    }
}

Same with an argument that is inherited from a base class and an interface.

Answer 29

Programmers moving from C/C++ may miss this one:

In C#, % (modulus operator) works on floats!

Answer 30

Apologies for posting so late, I am new to Stack Overflow so missed the earlier opportunity.

I find that EventHandler<T> is a great feature of the framework that is underutilised.

Most C# developers I come across still define a custom event handler delegate when they are defining custom events, which is simply not necessary anymore.

Instead of:

public delegate void MyCustomEventHandler(object sender, MyCustomEventArgs e);

public class MyCustomEventClass 
{
    public event MyCustomEventHandler MyCustomEvent;
}

you can go:

public class MyCustomEventClass 
{
    public event EventHandler<MyCustomEventArgs> MyCustomEvent;
}

which is a lot more concise, plus you don't get into the dilemma of whether to put the delegate in the .cs file for the class that contains the event, or the EventArgs derived class.