Rougamo.Fody 3.0.1-priview-1720089186

This is a prerelease version of Rougamo.Fody.
There is a newer version of this package available.
See the version list below for details.
dotnet add package Rougamo.Fody --version 3.0.1-priview-1720089186                
NuGet\Install-Package Rougamo.Fody -Version 3.0.1-priview-1720089186                
This command is intended to be used within the Package Manager Console in Visual Studio, as it uses the NuGet module's version of Install-Package.
<PackageReference Include="Rougamo.Fody" Version="3.0.1-priview-1720089186" />                
For projects that support PackageReference, copy this XML node into the project file to reference the package.
paket add Rougamo.Fody --version 3.0.1-priview-1720089186                
#r "nuget: Rougamo.Fody, 3.0.1-priview-1720089186"                
#r directive can be used in F# Interactive and Polyglot Notebooks. Copy this into the interactive tool or source code of the script to reference the package.
// Install Rougamo.Fody as a Cake Addin
#addin nuget:?package=Rougamo.Fody&version=3.0.1-priview-1720089186&prerelease

// Install Rougamo.Fody as a Cake Tool
#tool nuget:?package=Rougamo.Fody&version=3.0.1-priview-1720089186&prerelease                

Rougamo - 肉夹馍

中文 | English

What is Rougamo

Rougamo is an AOP component that takes effect at compile time. There are some well-known AOP components like Castle, Autofac and AspectCore. Unlike these components, which are implemented through dynamic proxying and IoC at runtime, Rougamo modifies target methods' IL during compilation. If you are familiar with the AOP component PostSharp, then Rougamo is similar to PostSharp.

Weaving Methods

Quick Start with Attribute

// 1.Add Rougamo.Fody package via NuGet
// 2.Define a class that inherits MoAttribute
public class LoggingAttribute : MoAttribute
{
    public override void OnEntry(MethodContext context)
    {
        // We can get method arguments, target class instance and MethodBase throughs MethodContext
        Log.Info("before method execute");
    }

    public override void OnException(MethodContext context)
    {
        Log.Error("while a exception was throwing", context.Exception);
    }

    public override void OnSuccess(MethodContext context)
    {
        Log.Info("method executed successfully");
    }

    public override void OnExit(MethodContext context)
    {
        Log.Info("before method exits");
    }
}

// 3.Apply Attribute to methods
public class Service
{
    [Logging]
    public static int Sync(Model model)
    {
        // ...
    }

    [Logging]
    public async Task<Data> Async(int id)
    {
        // ...
    }
}

Flag Matching

In the quick start section, I introduced how to weave codes into a specific method. However, in real business scenarios, there may be many methods in a project that require applying this Attribute. Then it will be tedious and invasive. So MoAttribute is designed to be applied to methods, classes, assemblies, and modules, and you can select methods that match the property MoAttribute.Flags. The following features can be filtered through Flags:

  • Method accessibility (public or non-public)
  • Is static method or not
  • Method category:normal method / property / getter / setter / constructor
// 1. Override Flags property, InstancePublic is the default value (public and instance method or property).
public class LoggingAttribute : MoAttribute
{
    // All public methods, both instance and static
    public override AccessFlags Flags => AccessFlags.Public | AccessFlags.Method;

    // All instance properties(include getters and setters)
    // public override AccessFlags Flags => AccessFlags.Instance | AccessFlags.Property;

    // ...
}

// 2. Apply
// 2.1. Apply to class
[Logging]
public class Service
{
    // ...
}

// 2.2. Apply to assembly
[assembly: Logging]

Attention, when Flags does not specify any of Method/PropertyGetter/PropertySetter/Property/Constructor, the default is the method and property (Method|Property). The reason is Method/PropertyGetter/PropertySetter/Property/Constructor cannot be specified before 2.0, and the default matches methods and properties. This logic will continue to be compatible in 2.0.

Weaving Through Interface

In the previous way, we mainly applied the Attribute to methods, classes, or assemblies, which requires us to modify code. This is an intrusive weaving method, which is not friendly for frequent AOP embedding scenarios. At this time, weaving through interfaces can greatly reduce or even avoid invasive weaving.

// 1. Interface weaving allows us to directly implement the IMo interface, and of course we can also inherit from MoAttribute.
public class LoggingMo : IMo
{
    // 1.1. Override Flags property
    public AccessFlags Flags => AccessFlags.All | AccessFlags.Method;

    public void OnEntry(MethodContext context)
    {
        // We can get method arguments, target class instance and MethodBase throughs MethodContext
        Log.Info("before method execute");
    }

    public void OnException(MethodContext context)
    {
        Log.Error("while a exception was throwing", context.Exception);
    }

    public void OnSuccess(MethodContext context)
    {
        Log.Info("method executed successfully");
    }

    public void OnExit(MethodContext context)
    {
        Log.Info("before method exits");
    }
}

// 2. Implement IRougamo interface
public class TheService : ITheService, IRougamo<LoggingMo>
{
    // ...
}

In the above example, we only needs to implement an empty interface IRougamo<LoggingMo>, and the methods that match the Flags defined by LoggingMo will be selected. You may have a question "Isn't this still about modifying the code? Isn't it invasive?" Yes, it is still invasive. But if your project has a common layer for encapsulation, such as all Service have to implement IService or inherit from Service which is define in common layer, then you can operate on the parent/base interface at this time:

// Common interface implements IRougamo
public interface IService : IRougamo<LoggingMo>
{
    // ...
}

// Bussiness interface implements common interface
public interface ITheService : IService
{
    // ...
}

public class TheService : ITheService
{
    // ...
}

Pattern Matching

Flag Matching is easy to use, but the matching granularity is too large. In this section, we will introduce the pattern matching introduced in version 2.0, which has more precise matching rules. The syntax refers to aspectj, but it is not exactly the same. So it is recommended to understand it before using it.

public class PatternAttribute : MoAttribute
{
    // Match all methods that method name starts with Get
    public override string? Pattern => "method(* *.Get*(..))";

    // Match all public static methods
    public override string? Pattern => "method(public static * *(..))";

    // Match all property getter
    public override string? Pattern => "getter(* *)";

    // Match all methods that return type is int[] or implements System.Collections.Generic.IEnumerable<int>
    public override string? Pattern => "method(int[]||System.Collections.Generic.IEnumerable<int>+ *(..))";
}

Basic Concepts

Flag matching overrides the Flags property, and pattern matching overrides the Pattern property. Since both flag matching and pattern matching are used for filtering methods, they cannot be used at the same time. Pattern matching has higher priority, Pattern is used when it is not null, otherwise Flags is used.

Pattern matching support seven matching rules:

  • method([modifier] returnType declaringType.methodName([parameters]))
  • getter([modifier] propertyType declaringType.propertyName)
  • setter([modifier] propertyType declaringType.propertyName)
  • property([modifier] propertyType declaringType.propertyName)
  • execution([modifier] returnType declaringType.methodName([parameters]))
  • attr(position [index] attributeType)
  • regex(REGEX)

getter, setter and property means property getter, property setter, property getter and setter. method means all normal methods(except getter, setter, constructor). execution means all method(execpt constructor). regex is a special case and will be introduced in Regex Matching.

Except for the special format of regex, the contents of the other five matching rules mainly include the following five (or below) parts:

  • [modifier],the access modifier can be omitted. When omitted, it means matching all. The access modifier includes the following seven:
    • private
    • internal
    • protected
    • public
    • privateprotected,即private protected
    • protectedinternal,即protected internal
    • static,it should be noted that omitting this access modifier means matching both static and instances. If you want to match only instances, you can use it with the logical modifier ! like !static
  • returnType,the method returns the value type or property type. The format of the type is more complex. For details, see Type Matching Format
  • declaringType,the type of the class in which the method/property is declared, For details, see ype Matching Format
  • methodName/propertyName,the name of the method/property. The name can use * for fuzzy matching, such as *Async, Get*, Get*V2, etc. * matches 0 or more characters
  • [parameters],method parameter list, Rougamo's parameter list matching is relatively simple, not as complicated as aspectj, and only supports arbitrary matching and full matching.
    • Use .. to match any number of parameters of any type.
    • Specify the number and type of parameters for matching. Parameter types are matched according to Type Matching Format. Rougamo cannot perform fuzzy matching on the number of parameters like aspectj. For example, int,..,double is not supported.
  • position Where the attributes apply to, uses * to match anywhere.
    • type Applies to types.
    • exec Applies to methods, properties, properties getter, properties setter.
    • para Applies to parameters. Must be used together with [index].
    • ret Applies to return value.
    • * Match all positions.
  • [index] Only needed when position is para. Usually, index is an integer, starts at 0, which means the first parameter, and uses * to match any parameter.

Type Matching Format

Type Format

First of all, we make it clear that there are several ways to express a certain type: type name; namespace + type name; assembly + namespace + type name. Since Rogamo's application limit is assembly, so Rogamo chooses to use namespace + type name to express a type. The connection between namespace and type name adopts our common point connection method, namely namespace.type name.

Nested Type

Rougamo uses / as the nested class connector, which is inconsistent with the connector + in usual programming habits. The main reason is that + is a special character, which means subclass. For easier reading, another symbol is used. For example, a.b.c.D/E means the namespace is a.b.c and the outer class is D and the nested class is E. Of course nested classes support multiple levels of nesting.

Generic Type

What needs to be declared first is that generics are the same as static. They match all when not declared, it means match both non-generic types and generic types. If you want to match only non-generic types or only generic types, Additional definitions are required, and the relevant definitions of generics are expressed using <>.

  • Only match non-generic types: a.b.C<!>, use logical not ! to indicate not matching any generics
  • Match any generic: a.b.C<..>, use two dots .. to match at least one generics of any type
  • Matches a specified number of generics of any type: a.b.C<,,>. The example means matching three generics of any type. Each added , means matching an additional generic of any type. a.b.C< > means matching a generic of any type
  • Open and closed generic types: those with undetermined generic types are called open generic types, such as List<T>, and those with determined generic types are called closed generic types, such as List<int> >. When writing a matching expression, if you want to specify a specific generic type instead of arbitrary matching as described above, then for open undetermined generic types, you can use our commonly used T1, T2, TA, TX, etc. indicate that for closed and determined generic types, the determined type can be used directly.
    public class Generic<T1, T2>
    {
        public static void M(T1 t1, int x, T2 t2) { }
    }
    
    public class TestAttribute : MoAttribute
    {
        // When defining a matching expression, for an open generic type, it does not need to be consistent with the generic name defined by the type. For example, it is called T1, T2 above, and TA, TB is used in the pattern.
        public override string? Pattern => "method(* *<TA,TB>.*(TA,int,TB))";
    }
    
  • Generic methods: In addition to classes that can define generic parameters, methods can also define generic parameters. The method of using generic parameters of a method is the same as that of a type, so there will be no additional introduction.
    public class Generic<T1, T2>
    {
        public static void M<T3, T4>(T1 t1, T2 t2, T3 t3, T4 t4) { }
    }
    
    public class TestAttribute : MoAttribute
    {
        public override string? Pattern => "method(* *<TA,TB>.*<TX, TY>(TA,TB,TX,TY))";
    
        // You can also use non-generic matching, any matching and any type matching
        // public override string? Pattern => "method(* *<TA,TB>.*<..>(TA,TB,*,*))";
    }
    
Fuzzy Matching

Two types of fuzzy matching were introduced earlier, one is name fuzzy matching *, and the other is parameter/generic arbitrary matching ... These two symbols are still used for type fuzzy matching.

As introduced in Type Format, the type format consists of two parts namespace.type name, so type fuzzy matching can be divided into: namespace matching, type name matching, generic matching, Subclass matching. Generic Type was just introduced in the previous section, Subclass Matching will be introduced in the next section. This section mainly describes the basic fuzzy matching rules of types.

  • Type name matching: Fuzzy matching of type names is very simple. You can use * to match 0 or more characters, such as *Service, Mock*, Next*Repo*V2, etc. It should be noted that * cannot directly match any nested type. For example, it is not feasible to use *Service* to match AbcService+Xyz. The nested type needs to be clearly stated, such as *Service/* , matching the nested class whose name ends with Service. If it is a second-level nested class, it also needs to be clearly pointed out *Service/*/*
  • Namespace Matching
    • Absent matching: When the namespace is absent, it means matching any namespace. For example, the expression Abc can match l.m.n.Abc or x.y.z.Abc
    • Exact match: Do not use any wildcards, write a complete namespace
    • Fuzzy name: The namespace has one or more segments, and each segment is connected with .. Just like the type name matching, the characters in each segment can be matched by themselves using *, such as *.x*z.ab*.vv
    • Multi-segment fuzzy: Use .. to match 0 or multiple namespaces. For example, *..xyz.Abc can match a.b.xyz.Abc or lmn.xyz.Abc, .. can also match Used multiple times, such as using a..internal..t*..Ab to match a.internal.tk.Ab and a.b.internal.c.t.u.Ab
Subclass Matching

We can use + to match itself and its subclasses. For example, method(a.b.c.IService+ *(..)) matches methods which return a type that implement interface a.b.c.IService. In addition, subclass matching can also be used with wildcards. For example, method(* *(*Provider+)) indicates that the matching method parameter has only one subclass and the parameter type is a subclass of a type ending with Provider.

Special Syntax

Primitive Types

For primitive types, Rougamo supports type abbreviations to make pattern look more concise and clear. The currently supported abbreviated types are bool, byte, short, int, long, sbyte, ushort, uint, ulong, char, string, float, double, decimal, object, void.

Nullable

Just like our usual programming, we can use ? to represent the Nullable type, for example int? is Nullable<int>. It should be noted that the Nullable syntax of reference types should not be regarded as the Nullable type. For example, string? is actually string. In Rougamo, write string directly instead of string?.

Tuple ValueTuple

When we write C# code, we can directly use brackets to represent ValueTuple, which is also supported in Rougamo. For example, (int, string) means ValueTuple<int, string> or Tuple<int, string>.

Task ValueTask

Now asynchronous programming is a basic programming method, so there will be many methods whose return value is Task or ValueTask. At the same time, if you want to be compatible with the two return values ​​of Task and ValueTask, patterns are need to use the logical operator || to connect, which will greatly increase the complexity of the pattern. Rougamo adds the familiar async keyword to match Task and ValueTask return values. For example, Task<int> and ValueTask<int> can be written as async int. For non-generic Type Task and ValueTask are written as async null. It should be noted that there is currently no way to match async void alone, void will match void and async void.

Simplify Type and Method Name

As mentioned earlier, the pattern of type consists of namespace.typeName. If we want to match any type, the standard writing method should be *..*, where *.. represents any namespace, followed by * represents any type name. For any type, we can simplify it as *. Similarly, the standard writing method of any method of any type should be *..*.*, we can also simplify this as *. So method(*..* *..*.*(..)) and method(* *(..)) express the same meaning.

Regex Matching

For each method, Rougamo will generate a string signature for it, and the regex match is the match for this string of signatures. Its signature format is modifiers returnType declaringType.methodName([parameters]).

  • modifiers contains two parts. One part is the accessibility modifier, namely private/protected/internal/public/privateprotected/protectedinternal, and the other part is whether the static method static is used. The static keyword is omitted for non-static methods. Separate the two parts with a space.
  • returnType/declaringType are all full names of namespace.typeName. It should be noted that all types in the regular matching signature are full names, and similar int cannot be used to match System.Int32
  • Generics, types and methods may contain generics. For closed generic types, just use the full name of the type. For open generic types, we abide by the following rules. Generics start from T1 and increase backward. , that is, T1/T2/T3..., the order of increase is in the order of declaringType first and then method. For details, please see the following examples.
  • parameters, parameters can be expanded by the full name of each parameter
  • Nested types, nested types are connected using /
namespace a.b.c;

public class Xyz
{
    // signature:public System.Int32 a.b.c.Xyz.M1(System.String)
    public int M1(string s) => default;

    // signature:public static System.Void a.b.c.Xyz.M2<T1>(T1)
    public static void M2<T>(T value) { }

    public class Lmn<TU, TV>
    {
        // signature:internal System.Threading.Tasks.Task<System.DateTime> a.b.c.Xyz/Lmn<T1,T2>.M3<T3,T4>(T1,T2,T3,T4)
        internal Task<DateTime> M3<TO, TP>(TU u, TV v, TO o, TP p) => Task.FromResult(DateTime.Now);

        // signature:private static System.Threading.Tasks.ValueTask a.b.c.Xyz/Lmn<T1,T2>.M4()
        private static async ValueTask M4() => await Task.Yeild();
    }
}

Regex Matching has the problem of being complicated to write, and it does not support subclass matching, so Regex Matching are generally not written. They are mainly used as a supplement to other matching rules to support some more complex name matching. Since Rougamo supports logical operations, it also gives more auxiliary space for Regex Matching. For example, we want to find the return value method of Task/ValueTask whose method name does not end with Async method(async null *(..) ) && regex(^\S+ (static )?\S+ \S+?(?<!Async)\().

Weaving Ability

Overwrite Method Arguments

In OnEntry, you can modify the parameter values of the method by modifying the elements in MethodContext.Arguments. In order to make it clear that you want to modify the method parameters, you also need to set MethodContext.RewriteArguments to true to confirm the rewriting. parameter.

public class DefaultValueAttribute : MoAttribute
{
    public override void OnEntry(MethodContext context)
    {
        context.RewriteArguments = true;

        var parameters = context.Method.GetParameters();
        for (var i = 0; i < parameters.Length; i++)
        {
            if (parameters[i].ParameterType == typeof(string) && context.Arguments[i] == null)
            {
                context.Arguments[i] = string.Empty;
            }
        }
    }
}

public class Test
{
    [DefaultValue]
    public string EmptyIfNull(string value) => value;
}

Modify Return Value

In the OnEntry and OnSuccess methods, you can modify the actual return value of the method by calling the ReplaceReturnValue method of MethodContext. Special attention should be paid to not modifying the return value directly through the ReturnValue property. ReplaceReturnValue contains some other logic may be updated later. Also note that the return value of Iterator/AsyncIterator cannot be modified.

public class TestAttribute : MoAttribute
{
    public override void OnEntry(MethodContext context)
    {
        context.ReplaceReturnValue(this, newReturnValue);
    }

    public override void OnSuccess(MethodContext context)
    {
        context.ReplaceReturnValue(this, newReturnValue);
    }
}

Exception Handle

In the OnException method, you can indicate that the exception has been handled and set the return value by calling the HandledException method of MethodContext. Similarly, do not directly set the exception to be handled and set the return value directly through the properties of ReturnValue and ExceptionHandled. .

public class TestAttribute : MoAttribute
{
    public override void OnException(MethodContext context)
    {
        context.HandledException(this, newReturnValue);
    }
}

Retry

The retry function can re-execute the current method when a specified exception is encountered or the return value is unexpected. To do this, you need set MethodContext.RetryCount value. After OnException and OnSuccess, if the value of MethodContext.RetryCount is greater than 0, the current method will be re-executed.

internal class RetryAttribute : MoAttribute
{
    public override void OnEntry(MethodContext context)
    {
        // Initialize the number of retries
        context.RetryCount = 3;
    }

    public override void OnException(MethodContext context)
    {
        // If an exception occurs, the number of retries will be reduced by one. When RetryCount is reduced to 0, it means that the upper limit of retries has been reached and no more attempts will be made.
        context.RetryCount--;
    }

    public override void OnSuccess(MethodContext context)
    {
        if (context.ReturnValue != ABC)
        {
            // The result is an unexpected reduction in the number of retries. When RetryCount decreases to 0, it means that the upper limit of retries has been reached and no more attempts will be made.
            context.RetryCount--;
        }
        else
        {
            // The result is as expected, directly set the number of retries to 0 and no longer retry.
            context.RetryCount = 0;
        }
    }
}

// The Test method will retry 3 times
[Retry]
public void Test()
{
    throw new Exception();
}

For exception handling retry scenarios, I created an independent project Rougamo.Retry. If you only want to retry a certain exception, you can use Rougamo directly. .Retry

Please note the following points when using the retry function:

  • When handling exceptions through MethodContext.HandledException() or modifying the return value through MethodContext.ReplaceReturnValue(), MethodContext.RetryCount will be set to 0 directly, because manually handling exceptions and modifying the return value means that you have decided the final result of the method, so there is no need to retry
  • OnEntry and OnExit of MoAttribute will only be executed once and will not be executed multiple times due to retries.
  • Try not to use the retry in ExMoAttribute unless you really know the actual processing logic. Think about the following code, ExMoAttribute cannot re-execute the entire external method after reporting an error inside Task
    public Task Test()
    {
      DoSomething();
    
      return Task.Run(() => DoOtherThings());
    }
    

Partially Weaving

Rougamo will weave all functions into the code by default, but generally not all functions are used. And with the iteration of the version, more and more functions are supported and more and more code is woven into it, which will increase the final assembly size. By specifying partial weaving, you can weave in only the functionality you need. Partial weaving is set up by overriding MoAttribute.Features.

Value functions
All Contains all functions, default value
OnEntry Only OnEntry, parameter values cannot be modified, and return values cannot be modified
OnException OnException only, exceptions cannot be handled
OnSuccess OnSuccess only, the return value cannot be modified
OnExit OnExit
RewriteArgs Contains OnEntry, and parameter values can be modified in OnEntry
EntryReplace Contains OnEntry, and the return value can be modified in OnEntry
ExceptionHandle Contains OnException, and exceptions can be handled in OnEntry
SuccessReplace Contains OnSuccess, and the return value can be modified in OnSuccess
ExceptionRetry Contains OnException, and can retry in OnException
SuccessRetry Contains OnSuccess, and can retry in OnSuccess
Retry Contains OnException and OnSuccess, and can retry in OnException and OnSuccess
Observe Contains OnEntry, OnException, OnSuccess and OnExit
NonRewriteArgs Contains all functions except modifying parameters
NonRetry Contains all functionality except retry
FreshArgs Update the newest parameters value into MethodContext.Arguments before calls OnException, OnSuccess and OnExit

Ignore Weaving

Rougamo has the ability to weave in batches. Although the current version provides richer matching rules, if the matching pattern is too complicated in order to exclude one or several methods, it will not be worth the gain. When excluding a specific method or methods, you can directly use IgnoreMoAttribute. When applied to a method, the method will ignore weaving. When applied to a class, all methods of the class will ignore weaving. When applied to the assembly, all methods in the assembly ignore weaving.

In addition, you can specify the ignored type when ignoring weaving. For example, if a method applies multiple MoAttribute, you can ignore one individually. If not specified, it means ignoring all.

// Current assembly ignores all weaving
[assembly: IgnoreMo]
// Current assembly ignores weaving of TheMoAttribute
[assembly: IgnoreMo(MoTypes = new[] { typeof(TheMoAttribute))]

// Current class ignores all weaving
[IgnoreMo]
class Class1
{
    // ...
}

// The current class ignores weaving of TheMoAttribute
[IgnoreMo(MoTypes = new[] { typeof(TheMoAttribute))]
class Class2
{
    // ...
}

Proxy Weaving

If you have used some third-party components to Attribute mark some methods, and now you want to perform aop operations on these marked methods, but do not want to manually add Rougamo's Attribute marks one by one. You can use a proxy in one step to complete aop weaving. If your project now has many obsolete methods marked with ObsoleteAttribute. You want to output the call stack log when the expired methods are called to check which entries are currently using these expired methods. This can also be done in this way.

public class ObsoleteProxyMoAttribute : MoAttribute
{
    public override void OnEntry(MethodContext context)
    {
        Log.Warning("The obsolete method was called:" + Environment.StackTrace);
    }
}

// Proxy at the assembly level, all methods marked with ObsoleteAttribute will have ObsoleteProxyMoAttribute applied
[assembly: MoProxy(typeof(ObsoleteAttribute), typeof(ObsoleteProxyMoAttribute))]

ExMoAttribute

When we implement MoAttribute, in the OnEntry/OnSuccess/OnException/OnExit method, when we obtain the return value type through MethodContext.ReturnValue, for the Task/ValueTask method that returns a value, there are different performances when using and not using async/await syntax. For example, when using async syntax for Task<int> M(), the type of MethodContext.ReturnValue is int, but when not using async syntax, the type is Task <int>.

This is not a bug, but an initial design. Just as when we use async syntax, we will return like return 123 for Task<int>, and when we do not use async syntax, we will return like Task.FromResult(123). Furthermore, the performance after compilation is different between using and not using async syntax. Using async syntax will generate a state machine type at compile time, which will not be discussed in details here. So this design is not only based on the habits when writing code, but also based on the actual compiled code structure.

Although the design is like this, many times we do not use async/await syntax for some simple method overloading, but we also hope that Rougamo can handle it like methods with async/await syntax. Then it is recommended to use ExMoAttribute at this time. Regardless of whether async syntax is used, it can be processed just like using async syntax.

Note that ExMoAttribute and MoAttribute have the following differences:

  • ExMoAttribute overridable method named ExOnEntry/ExOnException/ExOnSuccess/ExOnExit
  • The return value of ExMoAttribute is obtained through MethodContext.ExReturnValue, and the value obtained through MethodContext.ReturnValue will be the value of Task/ValueTask
  • Whether the return value of ExMoAttribute is replaced/set, it is obtained through MethodContext.ExReturnValueReplaced, and the value obtained through MethodContext.ReturnValueReplaced is generally true (because it is replaced with the Task returned by ContinueWith)
  • The return value type of ExMoAttribute is obtained through MethodContext.ExReturnType. What is the difference between ReturnType/RealReturnType/ExReturnType can be seen in the description of the respective attribute document or the type document description of ExMoAttribute
[Fact]
public async Task Test()
{
    Assert.Equal(1, Sync());
    Assert.Equal(-1, SyncFailed1());
    Assert.Throws<InvalidOperationException>(() => SyncFailed3());

    Assert.Equal(1, await NonAsync());
    Assert.Equal(-1, await NonAsyncFailed1());
    Assert.Equal(-1, await NonAsyncFailed2());
    await Assert.ThrowsAsync<InvalidOperationException>(() => NonAsyncFailed3());
    await Assert.ThrowsAsync<InvalidOperationException>(() => NonAsyncFailed4());

    Assert.Equal(1, await Async());
    Assert.Equal(-1, await AsyncFailed1());
    Assert.Equal(-1, await AsyncFailed2());
    await Assert.ThrowsAsync<InvalidOperationException>(() => AsyncFailed3());
    await Assert.ThrowsAsync<InvalidOperationException>(() => AsyncFailed4());
}

[FixedInt]
static int Sync() => int.MaxValue;

[FixedInt]
static int SyncFailed1() => throw new NotImplementedException();

[FixedInt]
static int SyncFailed3() => throw new InvalidOperationException();

[FixedInt]
static Task<int> NonAsync() => Task.FromResult(int.MinValue);

[FixedInt]
static Task<int> NonAsyncFailed1() => throw new NotImplementedException();

[FixedInt]
static Task<int> NonAsyncFailed2() => Task.Run(int () => throw new NotImplementedException());

[FixedInt]
static Task<int> NonAsyncFailed3() => throw new InvalidOperationException();

[FixedInt]
static Task<int> NonAsyncFailed4() => Task.Run(int () => throw new InvalidOperationException());

[FixedInt]
static async Task<int> Async()
{
    await Task.Yield();
    return int.MaxValue / 2;
}

[FixedInt]
static async Task<int> AsyncFailed1() => throw new NotImplementedException();

[FixedInt]
static async Task<int> AsyncFailed2()
{
    await Task.Yield();
    throw new NotImplementedException();
}

[FixedInt]
static async Task<int> AsyncFailed3() => throw new InvalidOperationException();

[FixedInt]
static async Task<int> AsyncFailed4()
{
    await Task.Yield();
    throw new InvalidOperationException();
}

class FixedIntAttribute : ExMoAttribute
{
    protected override void ExOnException(MethodContext context)
    {
        if (context.Exception is NotImplementedException)
        {
            context.HandledException(this, -1);
        }
    }

    protected override void ExOnSuccess(MethodContext context)
    {
        context.ReplaceReturnValue(this, 1);
    }
}

Mutex Weaving

Single Type Mutex

Since we have two weaving methods, Attribute tag and interface implementation, it may be applied at the same time, and if the content of the two weaving is the same, there will be repeated weaving. In order to avoid this as much as possible In this case, when the interface is defined, mutually exclusive types can be defined, that is, only one can take effect at the same time, and which one takes effect is determined according to Priority.

public class Mo1Attribute : MoAttribute
{
    // ...
}
public class Mo2Attribute : MoAttribute
{
    // ...
}
public class Mo3Attribute : MoAttribute
{
    // ...
}

public class Test : IRougamo<Mo1Attribute, Mo2Attribute>
{
    [Mo2]
    public void M1()
    {
        // Mo2Attribute is applied to the method, the priority is higher than the Mo1Attribute implemented by the interface, and the Mo2Attribute will be applied
    }

    [Mo3]
    public void M2()
    {
        // Mo1Attribute and Mo3Attribute are not mutually exclusive, both will be applied
    }
}

Multiple Type Mutex

IRougamo<,> can only be mutually exclusive with one type, IRepulsionsRougamo<,> can be mutually exclusive with multiple types.

public class Mo1Attribute : MoAttribute
{
}
public class Mo2Attribute : MoAttribute
{
}
public class Mo3Attribute : MoAttribute
{
}
public class Mo4Attribute : MoAttribute
{
}
public class Mo5Attribute : MoAttribute
{
}

public class TestRepulsion : MoRepulsion
{
    public override Type[] Repulsions => new[] { typeof(Mo2Attribute), typeof(Mo3Attribute) };
}

[assembly: Mo2]
[assembly: Mo5]

public class Class2 : IRepulsionsRougamo<Mo1Attribute, TestRepulsion>
{
    [Mo3]
    public void M1()
    {
        // Mo1 is mutually exclusive with Mo2 and Mo3, but since Mo3 has a higher priority than Mo1, when Mo1 does not take effect, all mutually exclusive types will take effect.
        // So eventually Mo2Attribute, Mo3Attribute, Mo5Attribute will be applied.
        Console.WriteLine("m1");
    }

    [Mo4]
    public void M2()
    {
        // Mo1 is mutually exclusive with Mo2 and Mo3, but since Mo1 has a higher priority than Mo2, Mo2 will not take effect
        // Eventually Mo1Attribute, Mo4Attribute, Mo5Attribute will be applied
        Console.WriteLine("m2");
    }
}

Through the above example, you may notice that this multi-type mutual exclusion is not mutual exclusion between multiple types, but the mutual exclusion of the first generic type and the type defined by the second generic type, and the second generic type is mutually exclusive. They are not mutually exclusive. Just like the above example, when Mo1Attribute does not take effect, the mutually exclusive Mo2Attribute and Mo3Attribute will take effect. It needs to be understood here that the reason for defining mutual exclusion is the possible repeated application of Attribute and empty interface implementation, not to exclude all weaving repetitions. At the same time, it is not recommended to use multiple mutual exclusion definitions, which is prone to logical confusion. It is recommended to carefully consider a set of unified rules before application weaving, rather than random definitions, and then try to use multiple mutual exclusions to solve problems.

Performance Optimization

Structs

To accomplish AOP operations, it is inevitable to create objects of your custom implementation of IMo or types derived from MoAttribute every time a method is called. These objects, created during method calls, will be garbage collected after the method invocation, leading to an unavoidable increase in GC burden. Even if we handwrite AOP code, the same scenario arises. However, we can reduce the GC pressure in various ways, and one of them is using structs instead of classes.

One commonly used approach in Rougamo is to mark classes, methods, or assemblies with an Attribute. However, we cannot define attributes for structs directly. Therefore, we need to define a struct that implements the IMo interface and then specify this struct through the RougamoAttribute:

struct ValueMo : IMo
{
    // Implement the interface, define AOP operations
}

[Rougamo(typeof(ValueMo))]
class Cls
{
    // If the project uses C# 11 and above syntax, you can directly use the following generic Attribute
    [Rougamo<ValueMo>]
    public void M() { }
}

Omit

In the Partially Weaving section, we discussed reducing woven code size by selecting woven features using Features. Here, we'll introduce another feature, IMo.MethodContextOmits, used to improve performance.

The MethodContext contains contextual information about the method and serves as a messenger passed between multiple IMo objects. However, there are times when we don't need all the information in these messages, and obtaining/storing this information has a significant cost. In such cases, we can use the MethodContextOmits property to specify the data that is not required.

Currently, MethodContextOmits can specify a combination of the following values:

  • None, the default value, indicating that all data is needed.
  • Mos, indicating that MethodContext.Mos property is not needed. This property contains all the IMo objects woven into the current method. If you are using structs, storing this property will involve boxing operations and will also increase an IReadOnlyList<IMo> object. Note: When using ExMoAttribute, do not specify this value.
  • Arguments, indicating that MethodContext.Arguments property is not needed. This property stores all input parameter values of the called method. If the parameters include value types, boxing operations will be performed, and an additional object[] object will be created. Note: If the Features property includes either Args or RewriteArgs or FreshArgs, specifying this value will be ineffective, and the arguments will still be stored.

Other

Setting MoAttribute Built-in Properties When Applying

MoAttribute comes with many built-in properties, such as Pattern, Order, etc. These properties can be directly overridden when inheriting from MoAttribute. However, there are times when we want to set these attributes when applying the attribute. For example, when applying multiple attributes to a method, we may want to set their respective Order for the method so that they execute in the desired order. Since the built-in properties of MoAttribute do not have a publicly accessible setter, we cannot set them directly. In such cases, we can use the new keyword to re-expose the setter.

public class TestAttribute : MoAttribute
{
    // Overriding the Order property of MoAttribute with the new keyword
    // Making the setter public
    // The virtual keyword is optional; if you are sure that no type will inherit from TestAttribute and override the Order property, you can omit virtual
    // Here, a default value is set for Order, but it can also be omitted
    public new virtual double Order { get; set; } = 10;
}

As for why we don't directly expose the setter for MoAttribute properties, it mainly considers friends using the framework as middleware. Middleware may set default values for some MoAttribute properties and may not want others to modify these properties when using the middleware, nor do they want to expose these property values for users to see. Unfortunately, once a parent class defines a property with a public setter, it cannot be hidden by a subclass. Therefore, the chosen approach is to default to hiding, allowing the subclass to decide whether to make it public or not.

Priority

  1. IgnoreMoAttribute
  2. Method MoAttribute
  3. Method MoProxyAttribute
  4. Type MoAttribute
  5. Type MoProxyAttribute
  6. Type IRougamo<>, IRougamo<,>, IRepulsionsRougamo<,>
  7. Assembly & Module MoAttribute

Configuration

After referencing Rougamo, a FodyWeavers.xml file will be generated in the project root directory during compilation, with the following format:

<Weavers xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:noNamespaceSchemaLocation="FodyWeavers.xsd">
  <Rougamo />
</Weavers>

The way to add configuration is to add attributes and values directly to the Rougamo node, such as <Rougamo enabled="false" />.

The following table shows all configuration items:

Name(former name) default value description
enabled true Whether to enable rougamo
composite-accessibility false Whether to use class+method comprehensive accessibility for matching. By default, only method accessibility is used for matching. For example, if the accessibility of a class is internal and the accessibility of a method is public, then by default the accessibility of the method is considered public. After setting this configuration to true, the accessibility of the method is considered internal
moarray-threshold 4 When the MoAttribute actually effective on the method reaches this value, it will be saved in an array. This configuration is used to optimize weaving code. In most cases, there is only one MoAttribute on a method. In this case, using an array to save it will generate more IL code when calling its method
iterator-returns(enumerable-returns) false Whether to save the return value of the iterator to MethodContext.ReturnValue. Use this function with caution. If the iterator generates a large amount of data, enabling this function will occupy the same amount of memory
reverse-call-nonentry(reverse-call-ending) true When there are multiple MoAttribute on a method, whether to execute OnException/OnSuccess/OnExit in the reverse order of OnEntry. By default, it is executed in reverse order
except-type-patterns Regular expression of the full name of the type. Types matching this expression will be globally excluded. Multiple regular expressions should be separated by commas or semicolons

FAQ

Q: First time contacting Rougamo, but it doesn’t work.
A: When contacting for the first time, please note that the project must directly depend on Rougamo.Fody to take effect. Indirect dependencies are invalid. For example, project A depends on B, and B references Rougamo.Fody. At this time, the weaving in project A cannot take effect, and project A needs to directly reference Rougamo.Fody.

Q: After using Rougamo to develop libraries, do other projects that reference my libraries still have to reference Rougamo.Fody?
A: After the library references Rougamo.Fody, you can manually modify the reference node in the project file and add PrivateAssets="contentfiles;analyzers". The modification is as follows (remember to modify the version number when copying). When others use the library, you don't need to depend on Rougamo.Fody directly, but you need to directly depend on the your libraries.

<PackageReference Include="Rougamo.Fody" Version="2.0.0" PrivateAssets="contentfiles;analyzers" />
Product Compatible and additional computed target framework versions.
.NET net5.0 was computed.  net5.0-windows was computed.  net6.0 was computed.  net6.0-android was computed.  net6.0-ios was computed.  net6.0-maccatalyst was computed.  net6.0-macos was computed.  net6.0-tvos was computed.  net6.0-windows was computed.  net7.0 was computed.  net7.0-android was computed.  net7.0-ios was computed.  net7.0-maccatalyst was computed.  net7.0-macos was computed.  net7.0-tvos was computed.  net7.0-windows was computed.  net8.0 was computed.  net8.0-android was computed.  net8.0-browser was computed.  net8.0-ios was computed.  net8.0-maccatalyst was computed.  net8.0-macos was computed.  net8.0-tvos was computed.  net8.0-windows was computed. 
.NET Core netcoreapp2.0 was computed.  netcoreapp2.1 was computed.  netcoreapp2.2 was computed.  netcoreapp3.0 was computed.  netcoreapp3.1 was computed. 
.NET Standard netstandard2.0 is compatible.  netstandard2.1 was computed. 
.NET Framework net461 was computed.  net462 was computed.  net463 was computed.  net47 was computed.  net471 was computed.  net472 was computed.  net48 was computed.  net481 was computed. 
MonoAndroid monoandroid was computed. 
MonoMac monomac was computed. 
MonoTouch monotouch was computed. 
Tizen tizen40 was computed.  tizen60 was computed. 
Xamarin.iOS xamarinios was computed. 
Xamarin.Mac xamarinmac was computed. 
Xamarin.TVOS xamarintvos was computed. 
Xamarin.WatchOS xamarinwatchos was computed. 
Compatible target framework(s)
Included target framework(s) (in package)
Learn more about Target Frameworks and .NET Standard.

NuGet packages (42)

Showing the top 5 NuGet packages that depend on Rougamo.Fody:

Package Downloads
HandeSoft.Core

Package Description

HandeSoft.Web.Core

Package Description

BotSharp.Abstraction

Package Description

Ray.Infrastructure

This client library is a infrastructure that including extensions and helpers etc.

HZY.Framework.Core

HZY Framework 核心 1、ScheduledAttribute 定时任务特性标记 2、IServerMetricMonitoringService 服务器指标监控 CPU、内存、硬盘、运行时长 3、HZY.Framework.DynamicApiController 动态Api控制器 4、HZY.Framework.DependencyInjection 依赖注入

GitHub repositories (5)

Showing the top 5 popular GitHub repositories that depend on Rougamo.Fody:

Repository Stars
RayWangQvQ/BiliBiliToolPro
B 站(bilibili)自动任务工具,支持docker、青龙、k8s等多种部署方式。敏感肌也能用。
dotnetcore/FreeSql
🦄 .NET aot orm, C# orm, VB.NET orm, Mysql orm, Postgresql orm, SqlServer orm, Oracle orm, Sqlite orm, Firebird orm, 达梦 orm, 人大金仓 orm, 神通 orm, 翰高 orm, 南大通用 orm, 虚谷 orm, 国产 orm, Clickhouse orm, DuckDB orm, TDengine orm, QuestDB orm, MsAccess orm.
SciSharp/BotSharp
The AI Agent Framework in .NET
2881099/FreeSql.AdminLTE
这是一个 .NETCore MVC 中间件,基于 AdminLTE 前端框架动态产生 FreeSql 实体的增删查改界面。
ThingsGateway/ThingsGateway
ThingsGateway is a cross platform high-performance edge acquisition gateway based on Net8, providing underlying PLC communication libraries, communication debugging software, and more.
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4.0.3 1,209 9/16/2024
4.0.3-preview-1726120802 95 9/12/2024
4.0.3-preview-1725957423 103 9/10/2024
4.0.2 496 9/9/2024
4.0.2-preview-1725956948 92 9/10/2024
4.0.2-preview-1725875652 91 9/9/2024
4.0.2-preview-1725466232 93 9/4/2024
4.0.1 2,608 9/2/2024
4.0.1-preview-1725141430 87 8/31/2024
4.0.0 5,880 8/10/2024
4.0.0-priview-1723306347 108 8/10/2024
4.0.0-priview-1722831925 85 8/5/2024
3.1.0 1,488 7/16/2024
3.0.2 433 7/8/2024
3.0.2-priview-1720363148 102 7/7/2024
3.0.2-priview-1720251661 100 7/6/2024
3.0.1 184 7/4/2024
3.0.1-priview-1720089186 105 7/4/2024
3.0.1-priview-1720085112 88 7/4/2024
3.0.0 3,293 5/4/2024
3.0.0-priview-1714754497 77 5/3/2024
3.0.0-priview-1714407561 129 4/29/2024
2.3.1 7,286 4/23/2024
2.3.1-priview-1713854631 113 4/23/2024
2.3.1-priview-1713791514 101 4/22/2024
2.3.0 3,756 3/10/2024
2.3.0-priview-1709894403 112 3/8/2024
2.2.0 2,908 1/20/2024
2.2.0-priview-1705656978 108 1/19/2024
2.2.0-priview-1705571301 102 1/18/2024
2.2.0-priview-1705566213 108 1/18/2024
2.2.0-priview-1702899195 181 12/18/2023
2.1.1 4,588 12/14/2023
2.1.1-priview-1702545048 141 12/14/2023
2.1.1-priview-1702542781 139 12/14/2023
2.0.1 1,243 11/16/2023
2.0.0 2,979 10/8/2023
2.0.0-priview-1696783135 134 10/8/2023
2.0.0-priview-1696592398 129 10/6/2023
2.0.0-priview-1695658688 155 9/25/2023
2.0.0-priview-1695465141 148 9/23/2023
2.0.0-priview-1680984436 220 4/8/2023
2.0.0-priview-1680981587 180 4/8/2023
1.4.1 11,329 3/12/2023
1.4.1-priview-1678603084 187 3/12/2023
1.4.1-priview-1678557697 188 3/11/2023
1.4.1-priview-1678557463 186 3/11/2023
1.4.0 2,641 3/1/2023
1.4.0-beta 358 2/27/2023
1.4.0-alpha 233 2/25/2023
1.3.4 55,672 2/17/2023
1.3.3 975 1/17/2023
1.3.2 18,193 12/20/2022
1.3.1 340 12/20/2022
1.3.1-beta 177 12/14/2022
1.3.0 1,280 12/8/2022 1.3.0 is deprecated because it has critical bugs.
1.2.3 346 1/17/2023
1.2.2 319 12/20/2022
1.2.2-beta 167 12/14/2022
1.2.1 694 11/29/2022
1.2.1-beta 162 11/29/2022
1.2.0 2,059 9/14/2022 1.2.0 is deprecated.
1.2.0-beta 182 9/12/2022
1.2.0-alpha2 172 9/12/2022
1.2.0-alpha1 179 8/31/2022
1.2.0-alpha 172 8/30/2022
1.1.4 372 11/29/2022
1.1.4-alpha 186 12/25/2022
1.1.3 530 9/11/2022 1.1.3 is deprecated because it has critical bugs.
1.1.2 1,646 8/22/2022
1.1.2-beta 179 8/22/2022
1.1.1 2,768 8/8/2022
1.1.1-beta 189 8/1/2022
1.1.0 629 7/28/2022
1.1.0-beta 204 7/15/2022
1.1.0-alpha4 187 6/24/2022
1.1.0-alpha3 174 6/24/2022
1.1.0-alpha2 173 6/23/2022
1.1.0-alpha1 175 6/22/2022
1.1.0-alpha 189 5/22/2022
1.0.3 710 5/6/2022
1.0.3-beta 192 4/26/2022
1.0.2 694 12/23/2021
1.0.1 7,732 11/23/2021
1.0.1-beta 4,918 11/23/2021

- [[#71](https://github.com/inversionhourglass/Rougamo/issues/71)] 修复blazor项目在发布时illink对程序集做裁减优化时产生的异常
 > 程序集主要描述信息基本存储在ModuleDefinition的MetadataSystem字段中,各类型的原数据也基本从该对象中读取。然而通过删除/清空MethodDefinition的CustomDebugInformation并不会影响MetadataSystem中的数据,同时,在将修改写入程序集时,MetadataSystem中绝大部分数据都将直接清空后重新写入,然而CustomDebugInformation是个例外,这就导致MethodDefinition上对CustomDebugInformations的删除/清空操作无效。所以对CustomDebugInformation的删除操作还需要从MetadataSystem中的删除。参考 [MetadataSystem.Clear()](https://github.com/jbevain/cecil/blob/8e1ae7b4ea67ccc38cb8db3ded6802643109ffd7/Mono.Cecil/MetadataSystem.cs#L137)
- [[#72](https://github.com/inversionhourglass/Rougamo/issues/72)] 修复Feature属性直接设置初始值的方式无效的问题

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