While going through new C# 7.0 features, I stuck up with discard feature. It says:
Discards are local variables which you can assign but cannot read
from. i.e. they are “write-only” local variables.
and, then, an example follows:
if (bool.TryParse("TRUE", out bool _))
What is real use case when this will be beneficial? I mean what if I would have defined it in normal way, say:
if (bool.TryParse("TRUE", out bool isOK))
The discards are basically a way to intentionally ignore local variables which are irrelevant for the purposes of the code being produced. It's like when you call a method that returns a value but, since you are interested only in the underlying operations it performs, you don't assign its output to a local variable defined in the caller method, for example:
public static void Main(string[] args)
{
// I want to modify the records but I'm not interested
// in knowing how many of them have been modified.
ModifyRecords();
}
public static Int32 ModifyRecords()
{
Int32 affectedRecords = 0;
for (Int32 i = 0; i < s_Records.Count; ++i)
{
Record r = s_Records[i];
if (String.IsNullOrWhiteSpace(r.Name))
{
r.Name = "Default Name";
++affectedRecords;
}
}
return affectedRecords;
}
Actually, I would call it a cosmetic feature... in the sense that it's a design time feature (the computations concerning the discarded variables are performed anyway) that helps keeping the code clear, readable and easy to maintain.
I find the example shown in the link you provided kinda misleading. If I try to parse a String as a Boolean, chances are I want to use the parsed value somewhere in my code. Otherwise I would just try to see if the String corresponds to the text representation of a Boolean (a regular expression, for example... even a simple if statement could do the job if casing is properly handled). I'm far from saying that this never happens or that it's a bad practice, I'm just saying it's not the most common coding pattern you may need to produce.
The example provided in this article, on the opposite, really shows the full potential of this feature:
public static void Main()
{
var (_, _, _, pop1, _, pop2) = QueryCityDataForYears("New York City", 1960, 2010);
Console.WriteLine($"Population change, 1960 to 2010: {pop2 - pop1:N0}");
}
private static (string, double, int, int, int, int) QueryCityDataForYears(string name, int year1, int year2)
{
int population1 = 0, population2 = 0;
double area = 0;
if (name == "New York City")
{
area = 468.48;
if (year1 == 1960) {
population1 = 7781984;
}
if (year2 == 2010) {
population2 = 8175133;
}
return (name, area, year1, population1, year2, population2);
}
return ("", 0, 0, 0, 0, 0);
}
From what I can see reading the above code, it seems that the discards have a higher sinergy with other paradigms introduced in the most recent versions of C# like tuples deconstruction.
For Matlab programmers, discards are far from being a new concept because the programming language implements them since very, very, very long time (probably since the beginning, but I can't say for sure). The official documentation describes them as follows (link here):
Request all three possible outputs from the fileparts function:
helpFile = which('help');
[helpPath,name,ext] = fileparts('C:\Path\data.txt');
The current workspace now contains three variables from fileparts: helpPath, name, and ext. In this case, the variables are small. However, some functions return results that use much more memory. If you do not need those variables, they waste space on your system.
Ignore the first output using a tilde (~):
[~,name,ext] = fileparts(helpFile);
The only difference is that, in Matlab, inner computations for discarded outputs are normally skipped because output arguments are flexible and you can know how many and which one of them have been requested by the caller.
I have seen discards used mainly against methods which return Task<T> but you don't want to await the output.
So in the example below, we don't want to await the output of SomeOtherMethod() so we could do something like this:
//myClass.cs
public async Task<bool> Example() => await SomeOtherMethod()
// example.cs
Example();
Except this will generate the following warning:
CS4014 Because this call is not awaited, execution of the
current method continues before the call is completed. Consider
applying the 'await' operator to the result of the call.
To mitigate this warning and essentially ensure the compiler that we know what we are doing, you can use a discard:
//myClass.cs
public async Task<bool> Example() => await SomeOtherMethod()
// example.cs
_ = Example();
No more warnings.
To add another use case to the above answers.
You can use a discard in conjunction with a null coalescing operator to do a nice one-line null check at the start of your functions:
_ = myParam ?? throw new MyException();
Many times I've done code along these lines:
TextBox.BackColor = int32.TryParse(TextBox.Text, out int32 _) ? Color.LightGreen : Color.Pink;
Note that this would be part of a larger collection of data, not a standalone thing. The idea is to provide immediate feedback on the validity of each field of the data they are entering.
I use light green and pink rather than the green and red one would expect--the latter colors are dark enough that the text becomes a bit hard to read and the meaning of the lighter versions is still totally obvious.
(In some cases I also have a Color.Yellow to flag something which is not valid but neither is it totally invalid. Say the parser will accept fractions and the field currently contains "2 1". That could be part of "2 1/2" so it's not garbage, but neither is it valid.)
Discard pattern can be used with a switch expression as well.
string result = shape switch
{
Rectangule r => $"Rectangule",
Circle c => $"Circle",
_ => "Unknown Shape"
};
For a list of patterns with discards refer to this article: Discards.
Consider this:
5 + 7;
This "statement" performs an evaluation but is not assigned to something. It will be immediately highlighted with the CS error code CS0201.
// Only assignment, call, increment, decrement, and new object expressions can be used as a statement
https://learn.microsoft.com/en-us/dotnet/csharp/language-reference/compiler-messages/cs0201?f1url=%3FappId%3Droslyn%26k%3Dk(CS0201)
A discard variable used here will not change the fact that it is an unused expression, rather it will appear to the compiler, to you, and others reviewing your code that it was intentionally unused.
_ = 5 + 7; //acceptable
It can also be used in lambda expressions when having unused parameters:
builder.Services.AddSingleton<ICommandDispatcher>(_ => dispatcher);
I was reading the Github repository about the Clean Code concepts applied to C#, and I was surprised that the pattern matching strategy was recommended for to avoid type checking (in addition
https://github.com/thangchung/clean-code-dotnet#avoid-type-checking-part-1
I can understand when you don't really have the control over types defined in a third party, but other than that I think it might be definitely better to define an interface to process some actions.
The example used in that repository is:
// Bad: btw this example cannot even work, the methods are not defined in Object. Going to fork and PR.
public Path TravelToTexas(object vehicle)
{
if (vehicle.GetType() == typeof(Bicycle))
{
vehicle.PeddleTo(new Location("texas"));
}
else if (vehicle.GetType() == typeof(Car))
{
vehicle.DriveTo(new Location("texas"));
}
}
// Good: parent class / interface
public Path TravelToTexas(Traveler vehicle)
{
vehicle.TravelTo(new Location("texas"));
}
or
// Good: pattern matching
public Path TravelToTexas(object vehicle)
{
if (vehicle is Bicycle bicycle)
{
bicycle.PeddleTo(new Location("texas"));
}
else if (vehicle is Car car)
{
car.DriveTo(new Location("texas"));
}
}
Except that pattern matching switch / is translates into something equivalent to if / else if / else using the is operator (translated itself obj as TargetType != null) + some conditions (and the fact that you don't have to declare some variables upfront).
My question is there any optimization that I am not aware of when using the pattern matching switch / is cause otherwise I don't really see the point of recommending this strategy...?
And the extract take from: https://learn.microsoft.com/en-us/dotnet/csharp/pattern-matching#when-clauses-in-case-expressions
To illustrate these new idioms, let's work with structures that
represent geometric shapes using pattern matching statements. You are
probably familiar with building class hierarchies and creating virtual
methods and overridden methods to customize object behavior based on
the runtime type of the object.
Those techniques aren't possible for data that isn't structured in a
class hierarchy. When data and methods are separate, you need other
tools. The new pattern matching constructs enable cleaner syntax to
examine data and manipulate control flow based on any condition of
that data. You already write if statements and switch that test a
variable's value. You write is statements that test a variable's type.
Pattern matching adds new capabilities to those statements.
It's not possible for example to use an Adapter pattern instead and basically wrap the entities of the third party into something on which you can have the control. I mean then except in the deadly case to get an uninformative object I don't really see the point of doing this.
(translated itself obj as TargetType != null)
Ok, that's not quite correct. Check the example on MSDN.
Old way:
public static double ComputeArea(object shape)
{
if (shape is Square)
{
var s = (Square)shape;
return s.Side * s.Side;
}
else if (shape is Circle)
{
var c = (Circle)shape;
return c.Radius * c.Radius * Math.PI;
}
// elided
throw new ArgumentException(
message: "shape is not a recognized shape",
paramName: nameof(shape));
}
Note the explicit casts. Now the C# 7.0 version:
public static double ComputeAreaModernIs(object shape)
{
if (shape is Square s)
return s.Side * s.Side;
else if (shape is Circle c)
return c.Radius * c.Radius * Math.PI;
else if (shape is Rectangle r)
return r.Height * r.Length;
// elided
throw new ArgumentException(
message: "shape is not a recognized shape",
paramName: nameof(shape));
}
So what's changed? Well, the old way you had to 1) cast the object, and 2) use explicit casts in case of value types. That is, using as on a value type was an exception. Now, the is keyword is updated here to cast and assign a variable, but it also handles value types (not using as behind the scenes). This makes the code a bit more concise/easier to maintain. Or, in the words of MSDN
In this updated version, the is expression both tests the variable and assigns it to a new variable of the proper type. Also, notice that this version includes the Rectangle type, which is a struct. The new is expression works with value types as well as reference types.
Perhaps only a small benefit, but the MSDN documentation points out the new object is limited in scope, based on the if statement. You were probably already doing this before (casting inside an if block), but now it's automatic.
The answer is yes. Using pattern matching introduces a cost in terms of boxing. Sure, the new pattern matching is visually pleasing, but the performance will indeed suffer. Boxing is a well-known performance bottleneck.
The performance problem of the pattern matching is described in detail here:
https://github.com/dotnet/coreclr/issues/17670
Thus, this will indeed produce more performant code:
if (shape is Square)
{
var s = (Square)shape;
return s.Side * s.Side;
}
Than this:
if (shape is Square s) // Introduces boxing :(
{
return s.Side * s.Side;
}
All in all, do NOT use pattern matching on HOT paths.
I am new to linq, and this keeps popping on a null volume field. The file is unpredictable, and it will happen so I would like to put a 0 in where there is an exception. any quick and easy way to do it?
var qry =
from line in File.ReadAllLines("C:\\temp\\T.txt")
let myRecX = line.Split(',')
select new myRec()
{
price = Convert.ToDecimal( myRecX[0].Replace("price = ", "")) ,
volume = Convert.ToInt32(myRecX[1].Replace("volume =", "")),
dTime = Convert.ToDateTime( myRecX[2].Replace("timestamp =", ""))
};
If you would like to use a default when the incoming data is null, empty, or consists entirely of whitespace characters, you can do it like this:
volume = string.IsNullOrWhitesplace(myRecX[1])
? defaultVolume // <<== You can use any constant here
: Convert.ToInt32(myRecX[1].Replace("volume =", ""))
However, this is a "quick and dirty" way of achieving what you need, because the position of each named parameter remains hardcoded. A more robust way would be writing a mini-parser that pays attention to the names of attributes specified in the file, rather than replacing them with an empty string.
You could use something like this, which offers an expressive way to write what you want:
static TOutput Convert<TInput, TOutput>(
TInput value,
params Func<TInput, TOutput>[] options)
{
foreach (var option in options) {
try { return option(value); }
catch { }
}
throw new InvalidOperationException("No option succeeded.");
}
Used like:
select new myRec()
{
price = Convert(myRecX[0].Replace("price = ", ""),
input => Convert.ToDecimal(input),
or => 0M),
...
};
The function indirection and implicit array construction may incur a slight performance penalty, but it gives you a nice syntax with which to specify a number of possible conversions, where the first successful one is taken.
I think here there's an issue beyond the use of Linq.
In general is bad practice manipulating file data before sanitizing it.
Ever if the following question is on the filename (rather than it's content) is a good starting point to understand the concept of sanitizing input:
C# Sanitize File Name
After all yourself tells that your code lacks control of the file content, so before call:
let myRecX = line.Split(',')
I suggest define a private method like:
string SanitizeInputLine(string input) {
// here do whatever is needed to bring back input to
// a valid format in a way that subsequent calls will not
// fail
return input;
}
Applying it is straightforward;
let myRecX = SanitizeInputLine(line).Split(',')
As general rule never trust input.
Let me quote Chapter 10 named _All Input Is Evil!__ of Writing Secure Code by Howard/LeBlanc:
...you should never trust data until data is validated. Failure to do
so will render your application vulnerable. Or, put another way: all
input is evil until proven otherwise.
In some languages, almost everything can be used as a value. For example, some languages let you treat a block of code as a unit which can return a value.
In Scheme, a block of code wrapped in a let can return a value:
(define val
(let ()
(define a 10)
(define b 20)
(define c (+ a b))
c))
Perl 5 also supports blocks as values:
my $val = do
{
my $a = 100;
my $b = 200;
my $c = $a + $b;
$c;
};
The closest approximation to block values I could come up with in C# was to use a lambda that is cast and immediately called:
var val = ((Func<int>)(() =>
{
var a = 10;
var b = 20;
var c = a + b;
return c;
}))();
That's not too bad and is in fact exactly what is happening semantically with Scheme; the let is transformed to a lambda which is applied. It's at this point that I wouldn't mind macros in C# to clean up the syntactic clutter.
Is there an another way to get "block values" in C#?
Sorry, at first I seemed to have misread your question, but it seems delegates (as in your question) are exactly what you are looking for no? If you are interested in quickly grouping a set of different values together, and not necessarily logic, my previous answer still applies.
C# supports anonymous types.
var v = new { Amount = 108, Message = "Hello" };
The var keyword is introduced so you don't have to specify a type name.
Afterwards you can access the members as follows:
Console.WriteLine( v.Amount );
Another solution since C# 4.0 is using Tuples which basically group a set of unnamed values together.
var population = Tuple.Create(
"New York", 7891957, 7781984,
7894862, 7071639, 7322564, 8008278 );
You have to access them using population.Item1, population.Item2, ...
In some languages, almost everything can be used as a value.
You give 1 example, Scheme. Scheme is a functional language, (almost) everything in Scheme is a function rather than a value.
C# is now partially a functional language through the inclusion of Linq.
So the equivalents you seek are Linq queries and indeed lambda functions. If that's not enough, take a look at F#.
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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
?? (coalesce nulls) 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
Conditional (ternary) operator (?:) by JasonS
checked and unchecked operators by Binoj Antony
implicit and explicit operators by Flory
Language Features
Nullable types by Brad Barker
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
__arglist by Zac Bowling
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
This isn't C# per se, but I haven't seen anyone who really uses System.IO.Path.Combine() to the extent that they should. In fact, the whole Path class is really useful, but no one uses it!
I'm willing to bet that every production app has the following code, even though it shouldn't:
string path = dir + "\\" + fileName;
lambdas and type inference are underrated. Lambdas can have multiple statements and they double as a compatible delegate object automatically (just make sure the signature match) as in:
Console.CancelKeyPress +=
(sender, e) => {
Console.WriteLine("CTRL+C detected!\n");
e.Cancel = true;
};
Note that I don't have a new CancellationEventHandler nor do I have to specify types of sender and e, they're inferable from the event. Which is why this is less cumbersome to writing the whole delegate (blah blah) which also requires you to specify types of parameters.
Lambdas don't need to return anything and type inference is extremely powerful in context like this.
And BTW, you can always return Lambdas that make Lambdas in the functional programming sense. For example, here's a lambda that makes a lambda that handles a Button.Click event:
Func<int, int, EventHandler> makeHandler =
(dx, dy) => (sender, e) => {
var btn = (Button) sender;
btn.Top += dy;
btn.Left += dx;
};
btnUp.Click += makeHandler(0, -1);
btnDown.Click += makeHandler(0, 1);
btnLeft.Click += makeHandler(-1, 0);
btnRight.Click += makeHandler(1, 0);
Note the chaining: (dx, dy) => (sender, e) =>
Now that's why I'm happy to have taken the functional programming class :-)
Other than the pointers in C, I think it's the other fundamental thing you should learn :-)
From Rick Strahl:
You can chain the ?? operator so that you can do a bunch of null comparisons.
string result = value1 ?? value2 ?? value3 ?? String.Empty;
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.
From CLR via C#:
When normalizing strings, it is highly
recommended that you use
ToUpperInvariant instead of
ToLowerInvariant because Microsoft has
optimized the code for performing
uppercase comparisons.
I remember one time my coworker always changed strings to uppercase before comparing. I've always wondered why he does that because I feel it's more "natural" to convert to lowercase first. After reading the book now I know why.
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>()); } }
Avoid checking for null event handlers
Adding an empty delegate to events at declaration, suppressing the need to always check the event for null before calling it is awesome. Example:
public delegate void MyClickHandler(object sender, string myValue);
public event MyClickHandler Click = delegate {}; // add empty delegate!
Let you do this
public void DoSomething()
{
Click(this, "foo");
}
Instead of this
public void DoSomething()
{
// Unnecessary!
MyClickHandler click = Click;
if (click != null) // Unnecessary!
{
click(this, "foo");
}
}
Please also see this related discussion and this blog post by Eric Lippert on this topic (and possible downsides).
Everything else, plus
1) implicit generics (why only on methods and not on classes?)
void GenericMethod<T>( T input ) { ... }
//Infer type, so
GenericMethod<int>(23); //You don't need the <>.
GenericMethod(23); //Is enough.
2) simple lambdas with one parameter:
x => x.ToString() //simplify so many calls
3) anonymous types and initialisers:
//Duck-typed: works with any .Add method.
var colours = new Dictionary<string, string> {
{ "red", "#ff0000" },
{ "green", "#00ff00" },
{ "blue", "#0000ff" }
};
int[] arrayOfInt = { 1, 2, 3, 4, 5 };
Another one:
4) Auto properties can have different scopes:
public int MyId { get; private set; }
Thanks #pzycoman for reminding me:
5) Namespace aliases (not that you're likely to need this particular distinction):
using web = System.Web.UI.WebControls;
using win = System.Windows.Forms;
web::Control aWebControl = new web::Control();
win::Control aFormControl = new win::Control();
I didn't know the "as" keyword for quite a while.
MyClass myObject = (MyClass) obj;
vs
MyClass myObject = obj as MyClass;
The second will return null if obj isn't a MyClass, rather than throw a class cast exception.
Two things I like are Automatic properties so you can collapse your code down even further:
private string _name;
public string Name
{
get
{
return _name;
}
set
{
_name = value;
}
}
becomes
public string Name { get; set;}
Also object initializers:
Employee emp = new Employee();
emp.Name = "John Smith";
emp.StartDate = DateTime.Now();
becomes
Employee emp = new Employee {Name="John Smith", StartDate=DateTime.Now()}
The 'default' keyword in generic types:
T t = default(T);
results in a 'null' if T is a reference type, and 0 if it is an int, false if it is a boolean,
etcetera.
Attributes in general, but most of all DebuggerDisplay. Saves you years.
The # tells the compiler to ignore any
escape characters in a string.
Just wanted to clarify this one... it doesn't tell it to ignore the escape characters, it actually tells the compiler to interpret the string as a literal.
If you have
string s = #"cat
dog
fish"
it will actually print out as (note that it even includes the whitespace used for indentation):
cat
dog
fish
I think one of the most under-appreciated and lesser-known features of C# (.NET 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<Action<T>> 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.
"yield" would come to my mind. Some of the attributes like [DefaultValue()] are also among my favorites.
The "var" keyword is a bit more known, but that you can use it in .NET 2.0 applications as well (as long as you use the .NET 3.5 compiler and set it to output 2.0 code) does not seem to be known very well.
Edit: kokos, thanks for pointing out the ?? operator, that's indeed really useful. Since it's a bit hard to google for it (as ?? is just ignored), here is the MSDN documentation page for that operator: ?? Operator (C# Reference)
I tend to find that most C# developers don't know about 'nullable' types. Basically, primitives that can have a null value.
double? num1 = null;
double num2 = num1 ?? -100;
Set a nullable double, num1, to null, then set a regular double, num2, to num1 or -100 if num1 was null.
http://msdn.microsoft.com/en-us/library/1t3y8s4s(VS.80).aspx
one more thing about Nullable type:
DateTime? tmp = new DateTime();
tmp = null;
return tmp.ToString();
it is return String.Empty. Check this link for more details
Here are some interesting hidden C# features, in the form of undocumented C# keywords:
__makeref
__reftype
__refvalue
__arglist
These are undocumented C# keywords (even Visual Studio recognizes them!) that were added to for a more efficient boxing/unboxing prior to generics. They work in coordination with the System.TypedReference struct.
There's also __arglist, which is used for variable length parameter lists.
One thing folks don't know much about is System.WeakReference -- a very useful class that keeps track of an object but still allows the garbage collector to collect it.
The most useful "hidden" feature would be the yield return keyword. It's not really hidden, but a lot of folks don't know about it. LINQ is built atop this; it allows for delay-executed queries by generating a state machine under the hood. Raymond Chen recently posted about the internal, gritty details.
Unions (the C++ shared memory kind) in pure, safe C#
Without resorting to unsafe mode and pointers, you can have class members share memory space in a class/struct. Given the following class:
[StructLayout(LayoutKind.Explicit)]
public class A
{
[FieldOffset(0)]
public byte One;
[FieldOffset(1)]
public byte Two;
[FieldOffset(2)]
public byte Three;
[FieldOffset(3)]
public byte Four;
[FieldOffset(0)]
public int Int32;
}
You can modify the values of the byte fields by manipulating the Int32 field and vice-versa. For example, this program:
static void Main(string[] args)
{
A a = new A { Int32 = int.MaxValue };
Console.WriteLine(a.Int32);
Console.WriteLine("{0:X} {1:X} {2:X} {3:X}", a.One, a.Two, a.Three, a.Four);
a.Four = 0;
a.Three = 0;
Console.WriteLine(a.Int32);
}
Outputs this:
2147483647
FF FF FF 7F
65535
just add
using System.Runtime.InteropServices;
Using # for variable names that are keywords.
var #object = new object();
var #string = "";
var #if = IpsoFacto();
If you want to exit your program without calling any finally blocks or finalizers use FailFast:
Environment.FailFast()
Returning anonymous types from a method and accessing members without reflection.
// Useful? probably not.
private void foo()
{
var user = AnonCast(GetUserTuple(), new { Name = default(string), Badges = default(int) });
Console.WriteLine("Name: {0} Badges: {1}", user.Name, user.Badges);
}
object GetUserTuple()
{
return new { Name = "dp", Badges = 5 };
}
// Using the magic of Type Inference...
static T AnonCast<T>(object obj, T t)
{
return (T) obj;
}
Here's a useful one for regular expressions and file paths:
"c:\\program files\\oldway"
#"c:\program file\newway"
The # tells the compiler to ignore any escape characters in a string.
Mixins. Basically, if you want to add a feature to several classes, but cannot use one base class for all of them, get each class to implement an interface (with no members). Then, write an extension method for the interface, i.e.
public static DeepCopy(this IPrototype p) { ... }
Of course, some clarity is sacrificed. But it works!
Not sure why anyone would ever want to use Nullable<bool> though. :-)
True, False, FileNotFound?
This one is not "hidden" so much as it is misnamed.
A lot of attention is paid to the algorithms "map", "reduce", and "filter". What most people don't realize is that .NET 3.5 added all three of these algorithms, but it gave them very SQL-ish names, based on the fact that they're part of LINQ.
"map" => Select Transforms data
from one form into another
"reduce" => Aggregate Aggregates
values into a single result
"filter" => Where Filters data
based on a criteria
The ability to use LINQ to do inline work on collections that used to take iteration and conditionals can be incredibly valuable. It's worth learning how all the LINQ extension methods can help make your code much more compact and maintainable.
Environment.NewLine
for system independent newlines.
If you're trying to use curly brackets inside a String.Format expression...
int foo = 3;
string bar = "blind mice";
String.Format("{{I am in brackets!}} {0} {1}", foo, bar);
//Outputs "{I am in brackets!} 3 blind mice"
?? - coalescing operator
using (statement / directive) - great keyword that can be used for more than just calling Dispose
readonly - should be used more
netmodules - too bad there's no support in Visual Studio
#Ed, I'm a bit reticent about posting this as it's little more than nitpicking. However, I would point out that in your code sample:
MyClass c;
if (obj is MyClass)
c = obj as MyClass
If you're going to use 'is', why follow it up with a safe cast using 'as'? If you've ascertained that obj is indeed MyClass, a bog-standard cast:
c = (MyClass)obj
...is never going to fail.
Similarly, you could just say:
MyClass c = obj as MyClass;
if(c != null)
{
...
}
I don't know enough about .NET's innards to be sure, but my instincts tell me that this would cut a maximum of two type casts operations down to a maximum of one. It's hardly likely to break the processing bank either way; personally, I think the latter form looks cleaner too.
Maybe not an advanced technique, but one I see all the time that drives me crazy:
if (x == 1)
{
x = 2;
}
else
{
x = 3;
}
can be condensed to:
x = (x==1) ? 2 : 3;