This article covers New features of C# 4.0. Article has been divided into below sections. Introduction. Dynamic Lookup. Named and Optional Arguments. Features for COM interop. Variance. Relationship with Visual Basic. Resources. Other interested readings… 22 New Features of Visual Studio 2008 for .NET Professionals 50 New Features of SQL Server 2008
IIS 7.0 New features Introduction It is now close to a year since
Microsoft Visual C# 3.0 shipped as part of Visual Studio 2008. In
the VS Managed Languages team we are hard at work on creating
the next version of
the language (with
the unsurprising working title of C# 4.0), and this document is a first public description of
the planned language features as we currently see them. Please be advised that all this is in early stages of production and is subject to change. Part of
the reason for sharing our plans in public so early is precisely to get
the kind of feedback that will cause us to improve
the final product before it rolls out. Simultaneously with
the publication of this whitepaper, a first public CTP (community technology preview) of Visual Studio 2010 is going out as a Virtual PC image for everyone to try. Please use it to play and experiment with
the features, and let us know of any thoughts you have. We ask for your understanding and patience working with very early bits, where especially new or newly implemented features do not have
the quality or stability of a final product.
The aim of
the CTP is not to give you a productive work environment but to give you
the best possible impression of what we are working on for
the next release.
The CTP contains a number of walkthroughs, some of which highlight
the new language features of C# 4.0. Those are excellent for getting a hands-on guided tour through
the details of some common scenarios for
the features. You may consider this whitepaper a companion document to these walkthroughs, complementing them with a focus on
the overall language features and how they work, as opposed to
the specifics of
the concrete scenarios. C# 4.0
The major theme for C# 4.0 is dynamic programming. Increasingly, objects are “dynamic” in
the sense that their structure and behavior is not captured by a static type, or at least not one that
the compiler knows about when compiling your program. Some examples include a. objects from dynamic programming languages, such as Python or Ruby b. COM objects accessed through IDispatch c. ordinary .NET types accessed through reflection d. objects with changing structure, such as HTML DOM objects While C# remains a statically typed language, we aim to vastly improve
the interaction with such objects. A secondary theme is co-evolution with Visual Basic. Going forward we will aim to maintain
the individual character of each language, but at
the same time important new features should be introduced in both languages at
the same time. They should be differentiated more by style and feel than by feature set.
The new features in C# 4.0 fall into four groups: Dynamic lookup Dynamic lookup allows you to write method, operator and indexer calls, property and field accesses, and even object invocations which bypass
the C# static type checking and instead gets resolved at runtime. Named and optional parameters Parameters in C# can now be specified as optional by providing a default value for them in a member declaration. When
the member is invoked, optional arguments can be omitted. Furthermore, any argument can be passed by parameter name instead of position. COM specific interop features Dynamic lookup as well as named and optional parameters both help making programming against COM less painful than today. On top of that, however, we are adding a number of other small features that further improve
the interop experience. Variance It used to be that an IEnumerable<string> wasn’t an IEnumerable<object>. Now it is – C# embraces type safe “co-and contravariance” and common BCL types are updated to take advantage of that. Dynamic Lookup Dynamic lookup allows you a unified approach to invoking things dynamically. With dynamic lookup, when you have an object in your hand you do not need to worry about whether it comes from COM, IronPython,
the HTML DOM or reflection; you just apply operations to it and leave it to
the runtime to figure out what exactly those operations mean for that particular object. This affords you enormous flexibility, and can greatly simplify your code, but it does come with a significant drawback: Static typing is not maintained for these operations. A dynamic object is assumed at compile time to support any operation, and only at runtime will you get an error if it wasn’t so. Oftentimes this will be no loss, because
the object wouldn’t have a static type anyway, in other cases it is a tradeoff between brevity and safety. In order to facilitate this tradeoff, it is a design goal of C# to allow you to opt in or opt out of dynamic behavior on every single call.
The dynamic type C# 4.0 introduces a new static type called dynamic. When you have an object of type dynamic you can “do things to it” that are resolved only at runtime: dynamic d = GetDynamicObject(…); d.M(7);
The C# compiler allows you to call a method with any name and any arguments on d because it is of type dynamic. At runtime
the actual object that d refers to will be examined to determine what it means to “call M with an int” on it.
The type dynamic can be thought of as a special version of
the type object, which signals that
the object can be used dynamically. It is easy to opt in or out of dynamic behavior: any object can be implicitly converted to dynamic, “suspending belief” until runtime. Conversely, there is an “assignment conversion” from dynamic to any other type, which allows implicit conversion in assignment-like constructs: dynamic d = 7; // implicit conversion int i = d; // assignment conversion Dynamic operations Not only method calls, but also field and property accesses, indexer and operator calls and even delegate invocations can be dispatched dynamically: dynamic d = GetDynamicObject(…); d.M(7); // calling methods d.f = d.P; // getting and settings fields and properties d[“one”] = d[“two”]; // getting and setting thorugh indexers int i = d + 3; // calling operators string s = d(5,7); // invoking as a delegate
The role of
the C# compiler here is simply to package up
the necessary information about “what is being done to d”, so that
the runtime can pick it up and determine what
the exact meaning of it is given an actual object d. Think of it as deferring part of
the compiler’s job to runtime.
The result of any dynamic operation is itself of type dynamic. Runtime lookup At runtime a dynamic operation is dispatched according to
the nature of its target object d: COM objects If d is a COM object,
the operation is dispatched dynamically through COM IDispatch. This allows calling to COM types that don’t have a Primary Interop Assembly (PIA), and relying on COM features that don’t have a counterpart in C#, such as indexed properties and default properties. Dynamic objects If d implements
the interface IDynamicObject d itself is asked to perform
the operation. Thus by implementing IDynamicObject a type can completely redefine
the meaning of dynamic operations. This is used intensively by dynamic languages such as IronPython and IronRuby to implement their own dynamic object models. It will also be used by APIs, e.g. by
the HTML DOM to allow direct access to
the object’s properties using property syntax. Plain objects Otherwise d is a standard .NET object, and
the operation will be dispatched using reflection on its type and a C# “runtime binder” which implements C#’s lookup and overload resolution semantics at runtime. This is essentially a part of
the C# compiler running as a runtime component to “finish
the work” on dynamic operations that was deferred by
the static compiler. Example Assume
the following code: dynamic d1 = new Foo(); dynamic d2 = new Bar(); string s; d1.M(s, d2, 3, null); Because
the receiver of
the call to M is dynamic,
the C# compiler does not try to resolve
the meaning of
the call. Instead it stashes away information for
the runtime about
the call. This information (often referred to as
the “payload”) is essentially equivalent to: “Perform an instance method call of M with
the following arguments: 1. a string 2. a dynamic 3. a literal int 3 4. a literal object null” At runtime, assume that
the actual type Foo of d1 is not a COM type and does not implement IDynamicObject. In this case
the C# runtime binder picks up to finish
the overload resolution job based on runtime type information, proceeding as follows: 1. Reflection is used to obtain
the actual runtime types of
the two objects, d1 and d2, that did not have a static type (or rather had
the static type dynamic).
The result is Foo for d1 and Bar for d2. 2. Method lookup and overload resolution is performed on
the type Foo with
the call M(string,Bar,3,null) using ordinary C# semantics. 3. If
the method is found it is invoked; otherwise a runtime exception is thrown. Overload resolution with dynamic arguments Even if
the receiver of a method call is of a static type, overload resolution can still happen at runtime. This can happen if one or more of
the arguments have
the type dynamic: Foo foo = new Foo(); dynamic d = new Bar(); var result = foo.M(d);
The C# runtime binder will choose between
the statically known overloads of M on Foo, based on
the runtime type of d, namely Bar.
The result is again of type dynamic.
The Dynamic Language Runtime An important component in
the underlying implementation of dynamic lookup is
the Dynamic Language Runtime (DLR), which is a new API in .NET 4.0.
The DLR provides most of
the infrastructure behind not only C# dynamic lookup but also
the implementation of several dynamic programming languages on .NET, such as IronPython and IronRuby. Through this common infrastructure a high degree of interoperability is ensured, but just as importantly
the DLR provides excellent caching mechanisms which serve to greatly enhance
the efficiency of runtime dispatch. To
the user of dynamic lookup in C#,
the DLR is invisible except for
the improved efficiency. However, if you want to implement your own dynamically dispatched objects,
the IDynamicObject interface allows you to interoperate with
the DLR and plug in your own behavior. This is a rather advanced task, which requires you to understand a good deal more about
the inner workings of
the DLR. For API writers, however, it can definitely be worth
the trouble in order to vastly improve
the usability of e.g. a library representing an inherently dynamic domain. Open issues There are a few limitations and things that might work differently than you would expect. ·
The DLR allows objects to be created from objects that represent classes. However,
the current implementation of C# doesn’t have syntax to support this. · Dynamic lookup will not be able to find extension methods. Whether extension methods apply or not depends on
the static context of
the call (i.e. which using clauses occur), and this context information is not currently kept as part of
the payload. · Anonymous functions (i.e. lambda expressions) cannot appear as arguments to a dynamic method call.
The compiler cannot bind (i.e. “understand”) an anonymous function without knowing what type it is converted to. One consequence of these limitations is that you cannot easily use LINQ queries over dynamic objects: dynamic collection = …; var result = collection.Select(e => e + 5); If
the Select method is an extension method, dynamic lookup will not find it. Even if it is an instance method,
the above does not compile, because a lambda expression cannot be passed as an argument to a dynamic operation. There are no plans to address these limitations in C# 4.0. Named and Optional Arguments Named and optional parameters are really two distinct features, but are often useful together. Optional parameters allow you to omit arguments to member invocations, whereas named arguments is a way to provide an argument using
the name of
the corresponding parameter instead of relying on its position in
the parameter list. Some APIs, most notably COM interfaces such as
the Office automation APIs, are written specifically with named and optional parameters in mind. Up until now it has been very painful to call into these APIs from C#, with sometimes as many as thirty arguments having to be explicitly passed, most of which have reasonable default values and could be omitted. Even in APIs for .NET however you sometimes find yourself compelled to write many overloads of a method with different combinations of parameters, in order to provide maximum usability to
the callers. Optional parameters are a useful alternative for these situations. Optional parameters A parameter is declared optional simply by providing a default value for it: public void M(int x, int y = 5, int z = 7); Here y and z are optional parameters and can be omitted in calls: M(1, 2, 3); // ordinary call of M M(1, 2); // omitting z – equivalent to M(1, 2, 7) M(1); // omitting both y and z – equivalent to M(1, 5, 7) Named and optional arguments C# 4.0 does not permit you to omit arguments between commas as in M(1,,3). This could lead to highly unreadable comma-counting code. Instead any argument can be passed by name. Thus if you want to omit only y from a call of M you can write: M(1, z: 3); // passing z by name or M(x: 1, z: 3); // passing both x and z by name or even M(z: 3, x: 1); // reversing
the order of arguments All forms are equivalent, except that arguments are always evaluated in
the order they appear, so in
the last example
the 3 is evaluated before
the 1. Optional and named arguments can be used not only with methods but also with indexers and constructors. Overload resolution Named and optional arguments affect overload resolution, but
the changes are relatively simple: A signature is applicable if all its parameters are either optional or have exactly one corresponding argument (by name or position) in
the call which is convertible to
the parameter type. Betterness rules on conversions are only applied for arguments that are explicitly given – omitted optional arguments are ignored for betterness purposes. If two signatures are equally good, one that does not omit optional parameters is preferred. M(string s, int i = 1); M(object o); M(int i, string s = “Hello”); M(int i); M(5); Given these overloads, we can see
the working of
the rules above. M(string,int) is not applicable because 5 doesn’t convert to string. M(int,string) is applicable because its second parameter is optional, and so, obviously are M(object) and M(int). M(int,string) and M(int) are both better than M(object) because
the conversion from 5 to int is better than
the conversion from 5 to object. Finally M(int) is better than M(int,string) because no optional arguments are omitted. Thus
the method that gets called is M(int). Features for COM interop Dynamic lookup as well as named and optional parameters greatly improve
the experience of interoperating with COM APIs such as
the Office Automation APIs. In order to remove even more of
the speed bumps, a couple of small COM-specific features are also added to C# 4.0. Dynamic import Many COM methods accept and return variant types, which are represented in
the PIAs as object. In
the vast majority of cases, a programmer calling these methods already knows
the static type of a returned object from context, but explicitly has to perform a cast on
the returned value to make use of that knowledge. These casts are so common that they constitute a major nuisance. In order to facilitate a smoother experience, you can now choose to import these COM APIs in such a way that variants are instead represented using
the type dynamic. In other words, from your point of view, COM signatures now have occurrences of dynamic instead of object in them. This means that you can easily access members directly off a returned object, or you can assign it to a strongly typed local variable without having to cast. To illustrate, you can now say excel.Cells[1, 1].Value = "Hello"; instead of ((Excel.Range)excel.Cells[1, 1]).Value2 = "Hello"; and Excel.Range range = excel.Cells[1, 1]; instead of Excel.Range range = (Excel.Range)excel.Cells[1, 1]; Compiling without PIAs Primary Interop Assemblies are large .NET assemblies generated from COM interfaces to facilitate strongly typed interoperability. They provide great support at design time, where your experience of
the interop is as good as if
the types where really defined in .NET. However, at runtime these large assemblies can easily bloat your program, and also cause versioning issues because they are distributed independently of your application.
The no-PIA feature allows you to continue to use PIAs at design time without having them around at runtime. Instead,
the C# compiler will bake
the small part of
the PIA that a program actually uses directly into its assembly. At runtime
the PIA does not have to be loaded. Omitting ref Because of a different programming model, many COM APIs contain a lot of reference parameters. Contrary to refs in C#, these are typically not meant to mutate a passed-in argument for
the subsequent benefit of
the caller, but are simply another way of passing value parameters. It therefore seems unreasonable that a C# programmer should have to create temporary variables for all such ref parameters and pass these by reference. Instead, specifically for COM methods,
the C# compiler will allow you to pass arguments by value to such a method, and will automatically generate temporary variables to hold
the passed-in values, subsequently discarding these when
the call returns. In this way
the caller sees value semantics, and will not experience any side effects, but
the called method still gets a reference. Open issues A few COM interface features still are not surfaced in C#. Most notably these include indexed properties and default properties. As mentioned above these will be respected if you access COM dynamically, but statically typed C# code will still not recognize them. There are currently no plans to address these remaining speed bumps in C# 4.0. Variance An aspect of generics that often comes across as surprising is that
the following is illegal: IList<string> strings = new List<string>(); IList<object> objects = strings;
The second assignment is disallowed because strings does not have
the same element type as objects. There is a perfectly good reason for this. If it were allowed you could write: objects[0] = 5; string s = strings[0]; Allowing an int to be inserted into a list of strings and subsequently extracted as a string. This would be a breach of type safety. However, there are certain interfaces where
the above cannot occur, notably where there is no way to insert an object into
the collection. Such an interface is IEnumerable<T>. If instead you say: IEnumerable<object> objects = strings; There is no way we can put
the wrong kind of thing into strings through objects, because objects doesn’t have a method that takes an element in. Variance is about allowing assignments such as this in cases where it is safe.
The result is that a lot of situations that were previously surprising now just work. Covariance In .NET 4.0
the IEnumerable<T> interface will be declared in
the following way: public interface IEnumerable<out T> : IEnumerable { IEnumerator<T> GetEnumerator(); } public interface IEnumerator<out T> : IEnumerator { bool MoveNext(); T Current { get; } }
The “out” in these declarations signifies that
the T can only occur in output position in
the interface –
the compiler will complain otherwise. In return for this restriction,
the interface becomes “covariant” in T, which means that an IEnumerable<A> is considered an IEnumerable<B> if A has a reference conversion to B. As a result, any sequence of strings is also e.g. a sequence of objects. This is useful e.g. in many LINQ methods. Using
the declarations above: var result = strings.Union(objects); // succeeds with an IEnumerable<object> This would previously have been disallowed, and you would have had to to some cumbersome wrapping to get
the two sequences to have
the same element type. Contravariance Type parameters can also have an “in” modifier, restricting them to occur only in input positions. An example is IComparer<T>: public interface IComparer<in T> { public int Compare(T left, T right); }
The somewhat baffling result is that an IComparer<object> can in fact be considered an IComparer<string>! It makes sense when you think about it: If a comparer can compare any two objects, it can certainly also compare two strings. This property is referred to as contravariance. A generic type can have both in and out modifiers on its type parameters, as is
the case with
the Func<…> delegate types: public delegate TResult Func<in TArg, out TResult>(TArg arg); Obviously
the argument only ever comes in, and
the result only ever comes out. Therefore a Func<object,string> can in fact be used as a Func<string,object>. Limitations Variant type parameters can only be declared on interfaces and delegate types, due to a restriction in
the CLR. Variance only applies when there is a reference conversion between
the type arguments. For instance, an IEnumerable<int> is not an IEnumerable<object> because
the conversion from int to object is a boxing conversion, not a reference conversion. Also please note that
the CTP does not contain
the new versions of
the .NET types mentioned above. In order to experiment with variance you have to declare your own variant interfaces and delegate types. COM Example Here is a larger Office automation example that shows many of
the new C# features in action. using System; using System.Diagnostics; using System.Linq; using Excel =
Microsoft.Office.Interop.Excel; using Word =
Microsoft.Office.Interop.Word; class Program { static void Main(string[] args) { var excel = new Excel.Application(); excel.Visible = true; excel.Workbooks.Add(); // optional arguments omitted excel.Cells[1, 1].Value = "Process Name"; // no casts; Value dynamically excel.Cells[1, 2].Value = "Memory Usage"; // accessed var processes = Process.GetProcesses() .OrderByDescending(p => p.WorkingSet) .Take(10); int i = 2; foreach (var p in processes) { excel.Cells[i, 1].Value = p.ProcessName; // no casts excel.Cells[i, 2].Value = p.WorkingSet; // no casts i++; } Excel.Range range = excel.Cells[1, 1]; // no casts Excel.Chart chart = excel.ActiveWorkbook.Charts. Add(After: excel.ActiveSheet); // named and optional arguments chart.ChartWizard( Source: range.CurrentRegion, Title: "Memory Usage in " + Environment.MachineName); //named+optional chart.ChartStyle = 45; chart.CopyPicture(Excel.XlPictureAppearance.xlScreen, Excel.XlCopyPictureFormat.xlBitmap, Excel.XlPictureAppearance.xlScreen); var word = new Word.Application(); word.Visible = true; word.Documents.Add(); // optional arguments word.Selection.Paste(); } }
The code is much more terse and readable than
the C# 3.0 counterpart. Note especially how
the Value property is accessed dynamically. This is actually an indexed property, i.e. a property that takes an argument; something which C# does not understand. However
the argument is optional. Since
the access is dynamic, it goes through
the runtime COM binder which knows to substitute
the default value and call
the indexed property. Thus, dynamic COM allows you to avoid accesses to
the puzzling Value2 property of Excel ranges. Relationship with Visual Basic A number of
the features introduced to C# 4.0 already exist or will be introduced in some form or other in Visual Basic: · Late binding in VB is similar in many ways to dynamic lookup in C#, and can be expected to make more use of
the DLR in
the future, leading to further parity with C#. · Named and optional arguments have been part of Visual Basic for a long time, and
the C# version of
the feature is explicitly engineered with maximal VB interoperability in mind. · NoPIA and variance are both being introduced to VB and C# at
the same time. VB in turn is adding a number of features that have hitherto been a mainstay of C#. As a result future versions of C# and VB will have much better feature parity, for
the benefit of everyone. Resources All available resources concerning C# 4.0 can be accessed through
the C# Dev Center. Specifically, this white paper and other resources can be found at
the Code Gallery
site. Enjoy!
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