Rougamo.Fody 4.0.1

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dotnet add package Rougamo.Fody --version 4.0.1                
NuGet\Install-Package Rougamo.Fody -Version 4.0.1                
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="4.0.1" />                
For projects that support PackageReference, copy this XML node into the project file to reference the package.
paket add Rougamo.Fody --version 4.0.1                
#r "nuget: Rougamo.Fody, 4.0.1"                
#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=4.0.1

// Install Rougamo.Fody as a Cake Tool
#tool nuget:?package=Rougamo.Fody&version=4.0.1                

Rougamo - 肉夹馍

中文 | English

What is Rougamo

Rougamo is a static code weaving AOP component. Commonly used AOP components include Castle, Autofac, and AspectCore. Unlike these components, which typically implement AOP through dynamic proxy and IoC mechanisms at runtime, Rougamo achieves AOP by directly modifying the target method's IL code during compilation. Rougamo supports all types of methods, including synchronous/asynchronous methods, static/instance methods, constructors, and properties.

The origin of the name.

Rougamo, a type of traditional Chinese street food, is somewhat similar to a hamburger, as both involve meat being sandwiched between bread. Every time I mention AOP, I think of Rougamo, because AOP is just like Rougamo, do aspects around the mehod.

Rougamo's Advantages and Disadvantages

  • Advantages:

    1. Shorter Application Startup Time: Static weaving occurs at compile time, whereas dynamic proxies are set up at application startup.
    2. Support for All Methods: Rougamo supports all methods, including constructors, properties, and static methods. Dynamic proxies often only handle instance methods due to their reliance on IoC.
    3. Independent from Other Components: Rougamo does not require initialization and is easy and quick to use. Dynamic AOP relies on IoC components, which often need initialization at application startup and vary between different IoC components. Rougamo does not require initialization; you just define the aspect type and apply it.
  • Disadvantages:

    1. Larger Assembly Size: Since Rougamo is a compile-time AOP, it weaves additional code into the assembly at compile time, which increases the assembly size. However, this overhead is generally minimal and can be evaluated in your project through configuration options.
    2. Less Convenient IoC Interaction: Dynamic AOP can easily access the IoC container and inject types into aspect types due to its reliance on IoC. Rougamo, being a compile-time AOP, does not depend on IoC components and thus cannot directly interact with IoC through methods like constructor injection. However, it can still be used with IoC; see using IoC in Rougamo for details.

Basic Functionality Introduction

As an AOP component, Rougamo's primary function is to execute additional operations at key lifecycle points of a method. Rougamo supports four lifecycle points (or Join Points):

  1. Before method execution;
  2. After method execution successfully;
  3. After method throws an exception;
  4. When the method exits (regardless of whether it was successful or threw an exception, similar to try..finally).

Here's a simple example demonstrating how lifecycle points are expressed in code:

// Define a type inheriting from MoAttribute
public class TestAttribute : MoAttribute
{
    public override void OnEntry(MethodContext context)
    {
        // OnEntry corresponds to before method execution
    }

    public override void OnException(MethodContext context)
    {
        // OnException corresponds to after method throws an exception
    }

    public override void OnSuccess(MethodContext context)
    {
        // OnSuccess corresponds to after method execution successfully
    }

    public override void OnExit(MethodContext context)
    {
        // OnExit corresponds to when method exits
    }
}

At each lifecycle point, in addition to performing operations like logging, measuring method execution time, and APM instrumentation that don't affect method execution, you can also:

  1. Modify method parameters
  2. Intercept method execution
  3. Modify method return values
  4. Handle method exceptions
  5. Retry method execution

Applying Rougamo to Methods

The simplest and most direct way is to apply the defined Attribute directly to methods. This can include synchronous and asynchronous methods, instance methods and static methods, properties and property getters/setters, as well as instance and static constructors:

class Abc
{
    [Test]
    static Abc() { }

    [Test]
    public Abc() { }

    [Test]
    public int X { get; set; }

    public static Y
    {
        [Test]
        get;
        [Test]
        set;
    }

    [Test]
    public void M() { }

    [Test]
    public static async ValueTask MAsync() => await Task.Yield();
}

Applying attributes directly to methods is straightforward, but for common AOP types, adding the attribute to every method can be cumbersome. Rougamo also provides several bulk application methods:

  1. Class or assembly-level attributes
  2. Low-intrusive implementation of the empty interface IRougamo
  3. Specify an attribute as a proxy attribute and apply it to methods with the proxy attribute

When applying attributes in bulk, such as applying TestAttribute to a class, you typically don’t want every method in the class to receive TestAttribute. Instead, you may want to select methods that meet specific criteria. Rougamo offers two methods for method selection:

  1. Coarse-grained method feature matching, which allows specifying static, instance, public, private, property, constructor methods, etc.
  2. AspectJ-style class expressions, which provide AspectJ-like expressions for finer-grained matching, such as method names, return types, parameter types, etc.

Asynchronous Aspects

In modern development, asynchronous programming has become quite common. In the previous example, the method lifecycle nodes correspond to synchronous methods. If you need to perform asynchronous operations, you would have to manually block asynchronous operations to wait for the results, which can lead to resource wastage and performance loss. Rougamo provides asynchronous aspects in addition to synchronous aspects to better support asynchronous operations:

// Define a type that inherits from AsyncMoAttribute
public class TestAttribute : AsyncMoAttribute
{
    public override async ValueTask OnEntryAsync(MethodContext context) { }

    public override async ValueTask OnExceptionAsync(MethodContext context) { }

    public override async ValueTask OnSuccessAsync(MethodContext context) { }

    public override async ValueTask OnExitAsync(MethodContext context) { }
}

However, if asynchronous operations are not needed, it's still recommended to use synchronous aspects. For more information on asynchronous aspects, you can refer to Asynchronous Aspects.

Performance Optimization

Rougamo is a method-level AOP component. When applying Rougamo to methods, it instantiates related objects each time the method is called, which adds a burden to garbage collection (GC). Although this overhead is usually minimal and often negligible, Rougamo addresses performance impact by providing various optimization strategies:

  1. Partial Weaving: If you only want to record a call log before method execution and do not need other lifecycle nodes or exception handling, you can use partial weaving to include only the required functionalities. This reduces the actual IL code woven and minimizes the number of instructions executed at runtime.

  2. Structs: One difference between classes and structs is that classes are allocated on the heap, while structs are allocated on the stack. Using structs can allocate some Rougamo types on the stack, reducing GC pressure.

  3. Slimming MethodContext: MethodContext holds contextual information about the current method. This information requires additional objects and involves boxing and unboxing operations, such as for method parameters and return values. If you do not need this information, slimming down MethodContext can achieve certain optimization effects.

  4. Forced Synchronization: As discussed in Asynchronous Aspects, asynchronous aspects use ValueTask to optimize synchronous execution but still incur additional overhead. If asynchronous operations are not required, forcing synchronous aspects can avoid the extra costs of asynchronous aspects.

Learn More

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. 
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4.0.4 4,222 9/29/2024
4.0.4-preview-1727349912 95 9/26/2024
4.0.3 1,237 9/16/2024
4.0.3-preview-1726120802 99 9/12/2024
4.0.3-preview-1725957423 107 9/10/2024
4.0.2 509 9/9/2024
4.0.2-preview-1725956948 98 9/10/2024
4.0.2-preview-1725875652 97 9/9/2024
4.0.2-preview-1725466232 99 9/4/2024
4.0.1 2,634 9/2/2024
4.0.1-preview-1725141430 91 8/31/2024
4.0.0 6,326 8/10/2024
4.0.0-priview-1723306347 112 8/10/2024
4.0.0-priview-1722831925 89 8/5/2024
3.1.0 1,509 7/16/2024
3.0.2 443 7/8/2024
3.0.2-priview-1720363148 106 7/7/2024
3.0.2-priview-1720251661 104 7/6/2024
3.0.1 188 7/4/2024
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3.0.1-priview-1720085112 92 7/4/2024
3.0.0 3,511 5/4/2024
3.0.0-priview-1714754497 81 5/3/2024
3.0.0-priview-1714407561 134 4/29/2024
2.3.1 7,537 4/23/2024
2.3.1-priview-1713854631 117 4/23/2024
2.3.1-priview-1713791514 105 4/22/2024
2.3.0 3,799 3/10/2024
2.3.0-priview-1709894403 118 3/8/2024
2.2.0 2,985 1/20/2024
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2.2.0-priview-1702899195 185 12/18/2023
2.1.1 4,640 12/14/2023
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2.1.1-priview-1702542781 143 12/14/2023
2.0.1 1,254 11/16/2023
2.0.0 3,005 10/8/2023
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2.0.0-priview-1696592398 133 10/6/2023
2.0.0-priview-1695658688 157 9/25/2023
2.0.0-priview-1695465141 150 9/23/2023
2.0.0-priview-1680984436 222 4/8/2023
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1.4.1 11,550 3/12/2023
1.4.1-priview-1678603084 191 3/12/2023
1.4.1-priview-1678557697 192 3/11/2023
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1.4.0 2,673 3/1/2023
1.4.0-beta 365 2/27/2023
1.4.0-alpha 235 2/25/2023
1.3.4 57,675 2/17/2023
1.3.3 981 1/17/2023
1.3.2 18,513 12/20/2022
1.3.1 342 12/20/2022
1.3.1-beta 179 12/14/2022
1.3.0 1,282 12/8/2022 1.3.0 is deprecated because it has critical bugs.
1.2.3 348 1/17/2023
1.2.2 321 12/20/2022
1.2.2-beta 169 12/14/2022
1.2.1 696 11/29/2022
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1.2.0 2,065 9/14/2022 1.2.0 is deprecated.
1.2.0-beta 186 9/12/2022
1.2.0-alpha2 174 9/12/2022
1.2.0-alpha1 181 8/31/2022
1.2.0-alpha 174 8/30/2022
1.1.4 374 11/29/2022
1.1.4-alpha 190 12/25/2022
1.1.3 533 9/11/2022 1.1.3 is deprecated because it has critical bugs.
1.1.2 1,650 8/22/2022
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1.1.1 2,854 8/8/2022
1.1.1-beta 191 8/1/2022
1.1.0 631 7/28/2022
1.1.0-beta 206 7/15/2022
1.1.0-alpha4 189 6/24/2022
1.1.0-alpha3 176 6/24/2022
1.1.0-alpha2 175 6/23/2022
1.1.0-alpha1 177 6/22/2022
1.1.0-alpha 191 5/22/2022
1.0.3 715 5/6/2022
1.0.3-beta 196 4/26/2022
1.0.2 702 12/23/2021
1.0.1 7,743 11/23/2021
1.0.1-beta 4,920 11/23/2021