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block includes
include ../_util-fns
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We learned the basics of Angular Dependency injection in the
[Dependency Injection](./dependency-injection.html) chapter.
在[依赖注入](./dependency-injection.html)一章中我们已经学过了Angular依赖注入的基础知识。
Angular has a Hierarchical Dependency Injection system.
There is actually a tree of injectors
that parallel an application's component tree.
We can re-configure the injectors at any level of that component tree with
interesting and useful results.
Angular有一个多级依赖注入系统。
实际上,应用程序中有一个与组件树平行的注入器树(译注:平行是指结构完全相同且一一对应)。
我们可以使用一些有趣又有用的注入供应商,在组件树中的任何级别上重新配置注入器。
In this chapter we explore these points and write some code.
在本章中,我们将浏览这些要点,并写点代码儿来验证它。
p Try the #[+liveExampleLink2()].
p 试试#[+liveExampleLink2()].
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## The Injector Tree
## 注入器树
In the [Dependency Injection](./dependency-injection.html) chapter
we learned how to configure a dependency injector and how to retrieve dependencies where we need them.
在[依赖注入](./dependency-injection.html)一章中,我们学过如何配置依赖注入器,以及如何在我们需要时用它获取依赖。
We oversimplified. In fact, there is no such thing as ***the*** injector!
An application may have multiple injectors!
我们其实有点简化过度了。实际上,没有***那个(唯一的)***注入器这回事儿,因为一个应用中可能有很多注入器。
An Angular application is a tree of components. Each component instance has its own injector!
The tree of components parallels the tree of injectors.
一个Angular应用是一个组件树。每个组件实例都有自己的注入器
组件的树与注入器的树平行。
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Angular doesn't *literally* create a separate injector for each component.
Every component doesn't need its own injector and it would be horribly inefficient to create
masses of injectors for no good purpose.
Angular并没有像*字面上理解的*那样为每个组件都创建一个独立的注入器。
不是每个组件都需要它自己的注入器,盲目创建大量没有明确用途的注入器是非常低效的。
But it is true that every component ***has an injector*** (even if it shares that injector with another component)
and there may be many different injector instances operating at different levels of the component tree.
但说每个组件都**有一个注入器**是没问题的(即使它与其它组件共享注入器也应该算**有**),并且确实可能会有大量不同的注入器实例工作在组件树的不同级别。
It is useful to pretend that every component has its own injector.
我们可以假装每个组件都有自己的注入器,因为这样有助于思考和理解。
:marked
Consider a simple variation on the Tour of Heroes application consisting of three different components:
`HeroesApp`, `HeroesListComponent` and `HeroesCardComponent`.
The `HeroesApp` holds a single instance of `HeroesListComponent`.
The new twist is that the `HeroesListComponent` may hold and manage multiple instances of the `HeroesCardComponent`.
考虑《英雄指南》应用的一个简单变种,它由三个不同的组件构成:`HeroesApp`、`HeroesListComponent`和`HeroesCardComponent`。
`HeroesApp`保存了`HeroesListComponent`的一个单例。
新的变化是,`HeroesListComponent`可以保存和管理`HeroesCardComponent`的多个实例。
The following diagram represents the state of the component tree when there are three instances of `HeroesCardComponent`
open simultaneously.
下图展示了当`HeroesCardComponent`的三个实例同时展开时组件树的状态。
figure.image-display
img(src="/resources/images/devguide/dependency-injection/component-hierarchy.png" alt="injector tree" width="500")
:marked
Each component instance gets its own injector and an injector at one level is a child injector of the injector above it in the tree.
每个组件实例获得了它自己的注入器,并且每个级别上的注入器都是它上级节点的子注入器。
When a component at the bottom requests a dependency, Angular tries to satisfy that dependency with a provider registered in that component's own injector.
If the component's injector lacks the provider, it passes the request up to its parent component's injector.
If that injector can't satisfy the request, it passes it along to *its* parent component's injector.
The requests keep bubbling up until we find an injector that can handle the request or run out of component ancestors.
If we run out of ancestors, Angular throws an error.
当一个底层的组件申请获得一个依赖时Angular先尝试用该组件自己的注入器来满足它。
如果该组件的注入器没有找到对应的供应商,它就把这个申请转给它父组件的注入器来处理。
如果那个注入器也无法满足这个申请,它就继续转给*它的*父组件的注入器。
这个申请继续往上冒泡 —— 直到我们找到了一个能处理此申请的注入器或者超出了组件树中的祖先仍没找到。
如果超出了组件树中的祖先Angular就会抛出一个错误。
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There's a third possibility. An intermediate component can declare that it is the "host" component.
The hunt for providers will climb no higher than the injector for this host component.
We'll reserve discussion of this option for another day.
其实还有第三种可能性。一个中层的组件可以声称它自己是“宿主”组件。
向上查找供应商的过程会截止于这个“宿主”组件。
我们先保留这个问题,等改天再讨论这个选项。
:marked
Such a proliferation of injectors makes little sense until we consider the possibility that injectors at different levels can be
configured with different providers. We don't *have* to re-configure providers at every level. But we *can*.
除非注入器能在各个不同层次上使用不同的供应商进行配置,否则没必要让注入器分裂成这么多。
虽然我们并不是*必须*在每一层都重新配置供应商,但我们*可以*这样做。
If we don't re-configure, the tree of injectors appears to be flat. All requests bubble up to the root injector that we
configured with the `bootstrap` method.
如果我们完全没有进行过重新配置,注入器的树看起来将是“平面”的。所有的申请都会被冒泡到“根注入器”进行处理,也就是我们在`bootstrap`方法中配置的那个。
The ability to configure one or more providers at different levels opens up interesting and useful possibilities.
在不同层次上重新配置一个或多个供应商的能力,开启了一些既有趣又有用的可能性。
Lets return to our Car example.
Suppose we configured the root injector (marked as A) with providers for `Car`, `Engine` and `Tires`.
We create a child component (B) that defines its own providers for `Car` and `Engine`
This child is the parent of another component (C) that defines its own provider for `Car`.
让我们回到“汽车(Car)”类的例子。
假设我们使用`Car`、`Engine`和`Tires`的供应商配置过“根注入器”记为A
然后创建了一个子组件B它为`Car`和`Engine`类定义了自己的供应商。
这个子组件B又有另一个子组件CC也为`Car`定义了自己的供应商。
Behind the scenes each component sets up its own injector with one or more providers defined for that component itself.
幕后的情况是这样的:每个组件都设置了它自己的注入器,这些注入器都带着一个或多个为组件自身设计的供应商。
When we resolve an instance of `Car` at the deepest component (C),
its injector produces an instance of `Car` resolved by injector (C) with an `Engine` resolved by injector (B) and
`Tires` resolved by the root injector (A).
当我们在最底层的组件C中试图解析出一个`Car`的实例时它的注入器生产一个由注入器C解析出的`Car`类的实例,`Car`的实例带有一个由注入器B解析出的`Engine`类的实例,而`Engine`的实例带有一个由跟注入器A解析出的`Tires`类的实例。
figure.image-display
img(src="/resources/images/devguide/dependency-injection/injector-tree.png" alt="injector tree" width="600")
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## Component Injectors
## 组件注入器
In the previous section, we talked about injectors and how they are organized like a tree. Lookups follow the injector tree upwards until they find the requested thing to inject. But when do we actually want to provide providers on the root injector and when do we want to provide them on a child injector?
在前一节中我们讨论了注入器以及它们是如何被组织成一棵树的。Angular会沿着注入器树往上逐级查找直到发现了那个申请者要求注入的东西。
但是,我们什么时候该在根注入器上提供供应商,什么时候又该在子注入器上提供它们呢?
Consider you are building a component to show a list of super heroes that displays each super hero in a card with its name and superpower. There should also be an edit button that opens up an editor to change the name and superpower of our hero.
考虑我们正在构建一个组件,用来显示一个超级英雄的列表,它需要在每个卡片中显示一位超级英雄的名字和超能力。还要有一个编辑按钮来打开编辑器,以修改这位英雄的名字和超能力。
One important aspect of the editing functionality is that we want to allow multiple heroes to be in edit mode at the same time and that one can always either commit or cancel the proposed changes.
关于编辑功能的一个重要方面是,我们得允许多个英雄同时进入编辑模式,每一个都要始终允许提交或取消所做的修改。
Lets take a look at the `HeroesListComponent` which is the root component for this example.
我们看看`HeroesListComponent`,也就是这个例子中的根组件。
+makeExample('hierarchical-dependency-injection/ts/app/heroes-list.component.ts', null, 'app/heroes-list.component.ts')
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Notice that it imports the `HeroService` that weve used before so we can skip its declaration. The only difference is that weve used a more formal approach for our `Hero`model and defined it upfront as such.
注意,它导入了`HeroService`类,我们以前用到过这个类,所以直接跳过它的声明。
唯一的不同是,这里我们用一种更正规的方式使用`Hero`模型,把它定义在前面。
+makeExample('hierarchical-dependency-injection/ts/app/hero.ts', null, 'app/hero.ts')(format=".")
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Our `HeroesListComponent` defines a template that creates a list of `HeroCardComponent`s and `HeroEditorComponent`s, each bound to an instance of hero that is returned from the `HeroService`. Ok, thats not entirely true. It actually binds to an `EditItem<Hero>` which is a simple generic datatype that can wrap any type and indicate if the item being wrapped is currently being edited or not.
我们的`HeroesListComponent`组件定义了一个模板,来创建`HeroCardComponent`和`HeroEditorComponent`的列表,
它们的每个条目都绑定到一个由`HeroService`返回的Hero实例。
好吧,这么说也不完全对。它实际上绑定到了一个`EditItem<Hero>`实例,这是一个简单的泛型数据类型,它可以包裹任何类型的实例,
并额外添加一个`editing`属性,用来标记被包裹的实例是否正在编辑状态。
+makeExample('hierarchical-dependency-injection/ts/app/edit-item.ts', null, 'app/edit-item.ts')(format=".")
:marked
But how is `HeroCardComponent` implemented? Lets take a look.
但`HeroCardComponent`是怎么实现的?我们来看看。
+makeExample('hierarchical-dependency-injection/ts/app/hero-card.component.ts', null, 'app/hero-card.component.ts')
:marked
The `HeroCardComponent` is basically a component that defines a template to render a hero. Nothing more.
`HeroCardComponent`基本是一个组件,它定义了一个模板来渲染英雄。没别的。
Lets get to the interesting part and take a look at the `HeroEditorComponent`
让我们开始更有趣的部分,来看看`HeroEditorComponent`
+makeExample('hierarchical-dependency-injection/ts/app/hero-editor.component.ts', null, 'app/hero-editor.component.ts')
:marked
Now here its getting interesting. The `HeroEditorComponent`defines a template with an input to change the name of the hero and a `cancel` and a `save` button. Remember that we said we want to have the flexibility to cancel our editing and restore the old value? This means we need to maintain two copies of our `Hero` that we want to edit. Thinking ahead, this is a perfect use case to abstract it into its own generic service since we have probably more cases like this in our app.
现在,事情开始变得有趣儿了。`HeroEditorComponent`定义了一个模板,它有一个输入框来修改英雄的名字,以及一个`cancel`按钮和一个`save`按钮。
还记得吗?我们说过要能够灵活的取消编辑,并且回复原值吗?这意味着我们得维护这个待编辑`Hero`的两份实例。
想得超前一点,这是一个把它抽象成一个通用服务的完美案例,因为将来我们的应用中可能会需要更多与此类似的操作逻辑。
And this is where the `RestoreService` enters the stage.
该是`RestoreService`登场的时候了!
+makeExample('hierarchical-dependency-injection/ts/app/restore.service.ts', null, 'app/restore.service.ts')
:marked
All this tiny service does is define an API to set a value of any type which can be altered, retrieved or set back to its initial value. Thats exactly what we need to implement the desired functionality.
所有这些微型服务所做的都是定义一个API来设置一个任意类型的值它可以被修改、获取或者恢复成初始值。
这正是我们需要实现的功能。
Our `HeroEditComponent` uses this services under the hood for its `hero` property. It intercepts the `get` and `set` method to delegate the actual work to our `RestoreService` which in turn makes sure that we wont work on the original item but on a copy instead.
我们的`HeroEditComponent`组件悄悄把这个服务用在它的`hero`属性上。它拦截了`get`和`set`方法,并把真正的工作委托给我们的`RestoreService`服务,这样可以确保我们并不是在操作原始条目,而是一个副本。
At this point we may be scratching our heads asking what this has to do with component injectors?
Look closely at the metadata for our `HeroEditComponent`. Notice the `providers` property.
这时,我们可能挠着头问,这跟组件注入器有什么关系?
凑近我们的`HeroEditComponent`的元数据看看。注意看它的`providers`属性。
+makeExample('hierarchical-dependency-injection/ts/app/hero-editor.component.ts', 'providers')
:marked
This adds a `RestoreService` provider to the injector of the `HeroEditComponent`.
Couldnt we simply alter our bootstrap call to this?
它往`HeroEditComponent`的注入器中添加了一个`RestoreService`供应商。
不能简化点儿直接把我们的bootstrap方法改成这样吗
+makeExample('hierarchical-dependency-injection/ts/app/main.ts', 'bad-alternative')
:marked
Technically we could, but our component wouldnt quite behave the way it is supposed to. Remember that each injector treats the services that it provides as singletons. However, in order to be able to have multiple instances of `HeroEditComponent` edit multiple heroes at the same time we need to have multiple instances of the `RestoreService`. More specifically, each instance of `HeroEditComponent` needs to be bound to its own instance of the `RestoreService`.
从技术上讲,可以。但我们的组件将不会像预期的那样工作。记住,每个注入器都会把它提供的服务处理成单例。
可是,我们需要同时用多个`HeroEditComponent`实例来编辑多个英雄,这就意味着我们需要`RestoreService`的多个实例。
更明确的说,每个`HeroEditComponent`的实例都得绑定到它自己的`RestoreService`实例。
By configuring a provider for the `RestoreService` on the `HeroEditComponent`, we get exactly one new instance of the `RestoreService`per `HeroEditComponent`.
通过在`HeroEditComponent`上配置`RestoreService`的供应商,我们可以精确的实现每个`HeroEditComponent`都有一个`RestoreService`的新实例。
Does that mean that services arent singletons anymore in Angular 2? Yes and no.
There can be only one instance of a service type in a particular injector.
But we've learned that we can have multiple injectors operating at different levels of the application's component tree.
Any of those injectors could have its own instance of the service.
这是否意味着在Angular 2中服务再也不是单例的了也不是。
对某一个具体的注入器来讲,仍然是每个服务类型只有一个实例。
但我们已经知道,在应用程序组件树的各个不同级别上可以有多个注入器。
任何一个注入器都可以有它自己的服务实例。
If we defined a `RestoreService` provider only on the root component,
we would have exactly one instance of that service and it would be shared across the entire application.
如果我们只在根组件上定义了一个`RestoreService`供应商,我们就确实只有该服务的一个实例了,它会在整个应用程序中被共享。
Thats clearly not what we want in this scenario. We want each component to have its own instance of the `RestoreService`.
Defining (or re-defining) a provider at the component level creates a new instance of the service for each new instance
of that component. We've made the `RestoreService` a kind of "private" singleton for each `HeroEditComponent`,
scoped to that component instance and its child components.
但很明显,这我们不希望它出现在这个场景下。我们希望每个组件都有它自己的`RestoreService`实例。
在组件级别上定义(或重定义)一个供应商,将会为该组件创建一个新的服务实例。
我们已经把在每个`HeroEditComponent`中,把`RestoreService`做成了一种“私有”单例,它的作用范围被局限在了该组件的实例及其子组件中。
<!--
## Advanced Dependency Injection in Angular 2
Restrict Dependency Lookups
[TODO] (@Host) This has been postponed for now until we come up with a decent use case
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## Dependency Visibility
[TODO] (providers vs viewProviders) This has been postponed for now until come up with a decent use case
-->