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How to use reverse dependency in Go?

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Release: 2023-05-11 15:39:12
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Inversion dependency in Go language is a very practical technology that can help developers better develop software. In this article, we will introduce in detail what inversion dependency is and demonstrate how to use it in Go language to optimize software.

1. What is reverse dependency

In traditional software development, there are dependencies between modules. Some modules are dependent on other modules, and some modules are dependent on other modules. This kind of dependency is very common in software, but it also brings many problems. Once the code of a module changes, it is likely to affect all other modules that depend on that module. This change may also cause the code that uses the module to need to be modified accordingly, which will increase the difficulty of code maintenance.

Inverting dependencies is a way to solve the above problems. The core idea is to flip dependencies around, making dependencies easier to manage. Specifically, we can abstract the module code and define an interface, and the dependencies between modules are no longer direct dependencies, but interact through the interface. In this way, when the code of a module changes, you only need to modify the implementation of the corresponding interface of the module, and other modules that rely on this module will not be affected.

In the Go language, there are two important concepts for reversing dependencies: interfaces and dependency injection. Below we will introduce these two concepts respectively and demonstrate how to use them in the Go language.

2. Interface

In the Go language, an interface is a collection of methods that define a behavior. Specifically, an interface defines a set of methods that can be called by other code, regardless of how the methods are implemented. This approach can make the code more flexible and easier to manage.

Let's look at an example. Suppose we want to develop a calculator program that can calculate the four operations of addition, subtraction, multiplication and division. We can define the following interface:

type Calculator interface {
    Add(a, b float64) float64
    Sub(a, b float64) float64
    Mul(a, b float64) float64
    Div(a, b float64) (float64, error)
}
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The above code defines a Calculator interface, which contains four methods: Add, Sub, Mul and Div. It should be noted here that the interface only defines the names and parameter types of these methods, but the specific implementation of the methods is not defined.

The reason why we define interfaces is to decouple dependencies from specific implementations. Suppose we now implement an adder and define the following Add method in the adder:

type Adder struct{}

func (a Adder) Add(x, y float64) float64 {
    return x + y
}
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Here we define an Adder type and implement the Add method in the Calculator interface. But note that our Adder type does not explicitly declare to implement the Calculator interface. This is because in the Go language, as long as the type implements all the methods in an interface, it can be regarded as implementing the interface.

In this way, if we want to use the adder in other code, we can use it as a Calculator interface without caring about the specific implementation of the Adder type. This is the process of inverting dependencies through interfaces.

3. Dependency Injection

In addition to interfaces, the Go language also provides another way to reverse dependencies: dependency injection. The so-called dependency injection refers to explicitly passing dependencies to other objects in the code. This approach can make the code more flexible and easier to manage.

In the Go language, we can implement dependency injection through constructors. In an application, we can pass dependencies through the constructor when creating an instance, so that the dependencies are explicitly passed to other objects.

Let's look at an example below. Suppose we want to develop a calculator program that contains four operations: addition, subtraction, multiplication, and division. We can implement it as follows:

type Calculator struct {
    adder adder
    suber suber
    muter muter
    diver diver
}

func NewCalculator(l *log.Logger) Calculator {
    return Calculator{
        adder: &Adder{logger: l},
        suber: &Suber{logger: l},
        muter: &Muter{logger: l},
        diver: &Diver{logger: l},
    }
}
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In the above code, we define a Calculator type, which has four private fields: adder, suber, muter and diver. These fields represent adders, subtractors, multipliers, and dividers respectively. In the constructor NewCalculator, we inject these dependencies into the Calculator type.

In each specific implementation, we will inject the corresponding dependencies into this type:

type Adder struct {
    logger *log.Logger
}

func (a *Adder) Add(x, y float64) float64 {
    a.logger.Printf("adding %f and %f", x, y)
    return x + y
}
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In the above code, we implement an Adder type, in which we pass in an Dependencies of type log.Logger. We use this dependency to log when the Add method is executed.

In this way, we use dependency injection to decouple the specific implementation, making the code easier to manage.

4. Summary

In this article, we introduced the concept of inverted dependencies in detail and demonstrated how to use interfaces and dependency injection to implement inverted dependencies in the Go language. Inverting dependencies can make the code more flexible and easier to manage, and can greatly reduce the difficulty of code maintenance. In actual development, we should try our best to use inverted dependencies to optimize our software design and improve code quality and maintainability.

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