23 KiB
HTTP
In this tutorial, you'll add the following data persistence features with help from
Angular's HttpClient
.
- The
HeroService
gets hero data with HTTP requests. - Users can add, edit, and delete heroes and save these changes over HTTP.
- Users can search for heroes by name.
When you're done with this page, the app should look like this .
Enable HTTP services
HttpClient
is Angular's mechanism for communicating with a remote server over HTTP.
To make HttpClient
available everywhere in the app,
- open the root
AppModule
, - import the
HttpClientModule
symbol from@angular/common/http
, - add it to the
@NgModule.imports
array.
Simulate a data server
This tutorial sample mimics communication with a remote data server by using the In-memory Web API module.
After installing the module, the app will make requests to and receive responses from the HttpClient
without knowing that the In-memory Web API is intercepting those requests,
applying them to an in-memory data store, and returning simulated responses.
This facility is a great convenience for the tutorial.
You won't have to set up a server to learn about HttpClient
.
It may also be convenient in the early stages of your own app development when the server's web api is ill-defined or not yet implemented.
Important: the In-memory Web API module has nothing to do with HTTP in Angular.
If you're just reading this tutorial to learn about HttpClient
, you can skip over this step.
If you're coding along with this tutorial, stay here and add the In-memory Web API now.
Install the In-memory Web API package from npm
npm install angular-in-memory-web-api --saveImport the InMemoryWebApiModule
and the InMemoryDataService
class,
which you will create in a moment.
Add the InMemoryWebApiModule
to the @NgModule.imports
array—
after importing the HttpClient
,
—while configuring it with the InMemoryDataService
.
The forRoot()
configuration method takes an InMemoryDataService
class
that primes the in-memory database.
The Tour of Heroes sample creates such a class
src/app/in-memory-data.service.ts
which has the following content:
This file replaces mock-heroes.ts
, which is now safe to delete.
When your server is ready, detach the In-memory Web API, and the app's requests will go through to the server.
Now back to the HttpClient
story.
{@a import-heroes}
Heroes and HTTP
Import some HTTP symbols that you'll need:
Inject HttpClient
into the constructor in a private property called http
.
Keep injecting the MessageService
. You'll call it so frequently that
you'll wrap it in private log
method.
Define the heroesUrl
with the address of the heroes resource on the server.
Get heroes with HttpClient
The current HeroService.getHeroes()
uses the RxJS of()
function to return an array of mock heroes
as an Observable<Hero[]>
.
Convert that method to use HttpClient
Refresh the browser. The hero data should successfully load from the mock server.
You've swapped of
for http.get
and the app keeps working without any other changes
because both functions return an Observable<Hero[]>
.
Http methods return one value
All HttpClient
methods return an RxJS Observable
of something.
HTTP is a request/response protocol. You make a request, it returns a single response.
In general, an observable can return multiple values over time.
An observable from HttpClient
always emits a single value and then completes, never to emit again.
This particular HttpClient.get
call returns an Observable<Hero[]>
, literally "an observable of hero arrays". In practice, it will only return a single hero array.
HttpClient.get returns response data
HttpClient.get
returns the body of the response as an untyped JSON object by default.
Applying the optional type specifier, <Hero[]>
, gives you a typed result object.
The shape of the JSON data is determined by the server's data API. The Tour of Heroes data API returns the hero data as an array.
Other APIs may bury the data that you want within an object.
You might have to dig that data out by processing the Observable
result
with the RxJS map
operator.
Although not discussed here, there's an example of map
in the getHeroNo404()
method included in the sample source code.
Error handling
Things go wrong, especially when you're getting data from a remote server.
The HeroService.getHeroes()
method should catch errors and do something appropriate.
To catch errors, you "pipe" the observable result from http.get()
through an RxJS catchError()
operator.
Import the catchError
symbol from rxjs/operators
, along with some other operators you'll need later.
Now extend the observable result with the .pipe()
method and
give it a catchError()
operator.
The catchError()
operator intercepts an Observable
that failed.
It passes the error an error handler that can do what it wants with the error.
The following handleError()
method reports the error and then returns an
innocuous result so that the application keeps working.
handleError
The following errorHandler()
will be shared by many HeroService
methods
so it's generalized to meet their different needs.
Instead of handling the error directly, it returns an error handler function to catchError
that it
has configured with both the name of the operation that failed and a safe return value.
After reporting the error to console, the handler constructs a user friendly message and returns a safe value to the app so it can keep working.
Because each service method returns a different kind of Observable
result,
errorHandler()
takes a type parameter so it can return the safe value as the type that the app expects.
Tap into the Observable
The HeroService
methods will tap into the flow of observable values
and send a message (via log()
) to the message area at the bottom of the page.
They'll do that with the RxJS tap
operator,
which looks at the observable values, does something with those values,
and passes them along.
The tap
call back doesn't touch the values themselves.
Here is the final version of getHeroes
with the tap
that logs the operation.
Get hero by id
Most web APIs support a get by id request in the form api/hero/:id
(such as api/hero/11
).
Add a HeroService.getHero()
method to make that request:
There are three significant differences from getHeroes()
.
- it constructs a request URL with the desired hero's id.
- the server should respond with a single hero rather than an array of heroes.
- therefore,
getHero
returns anObservable<Hero>
("an observable of Hero objects") rather than an observable of hero arrays .
Update heroes
Editing a hero's name in the hero detail view. As you type, the hero name updates the heading at the top of the page. But when you click the "go back button", the changes are lost.
If you want changes to persist, you must write them back to the server.
At the end of the hero detail template, add a save button with a click
event
binding that invokes a new component method named save()
.
Add the following save()
method, which persists hero name changes using the hero service
updateHero()
method and then navigates back to the previous view.
Add HeroService.updateHero()
The overall structure of the updateHero()
method is similar to that of
getHeroes()
, but it uses http.put()
to persist the changed hero
on the server.
The HttpClient.put()
method takes three parameters
- the URL
- the data to update (the modified hero in this case)
- options
The URL is unchanged. The heroes web API knows which hero to update by looking at the hero's id
.
The heroes web API expects a special header in HTTP save requests.
That header is in the httpOptions
constant defined in the HeroService
.
Refresh the browser, change a hero name, save your change, and click the "go back" button. The hero now appears in the list with the changed name.
Add a new hero
To add a hero, this app only needs the hero's name. You can use an input
element paired with an add button.
Insert the following into the HeroesComponent
template, just after
the heading:
In response to a click event, call the component's click handler and then clear the input field so that it's ready for another name.
When the given name is non-blank, the handler creates a Hero
-like object
from the name (it's only missing the id
) and passes it to the services addHero()
method.
When addHero
saves successfully, the subscribe
callback
receives the new hero and pushes it into to the heroes
list for display.
You'll write HeroService.addHero
in the next section.
Add HeroService.addHero()
Add the following addHero()
method to the HeroService
class.
HeroService.addHero()
differs from updateHero
in two ways.
- it calls
HttpClient.post()
instead ofput()
. - it expects the server to generates an id for the new hero,
which it returns in the
Observable<Hero>
to the caller.
Refresh the browser and add some heroes.
Delete a hero
Each hero in the heroes list should have a delete button.
Add the following button element to the HeroesComponent
template, after the hero
name in the repeated <li>
element.
The HTML for the list of heroes should look like this:
To position the delete button at the far right of the hero entry,
add some CSS to the heroes.component.css
. You'll find that CSS
in the final review code below.
Add the delete()
handler to the component.
Although the component delegates hero deletion to the HeroService
,
it remains responsible for updating its own list of heroes.
The component's delete()
method immediately removes the hero-to-delete from that list,
anticipating that the HeroService
will succeed on the server.
There's really nothing for the component to do with the Observable
returned by
heroService.delete()
. It must subscribe anyway.
If you neglect to subscribe()
, the service will not send the delete request to the server!
As a rule, an Observable
does nothing until something subscribes!
Confirm this for yourself by temporarily removing the subscribe()
,
clicking "Dashboard", then clicking "Heroes".
You'll see the full list of heroes again.
Add HeroService.deleteHero()
Add a deleteHero()
method to HeroService
like this.
Note that
- it calls
HttpClient.delete
. - the URL is the heroes resource URL plus the
id
of the hero to delete - you don't send data as you did with
put
andpost
. - you still send the
httpOptions
.
Refresh the browser and try the new delete functionality.
Search by name
In this last exercise, you learn to chain Observable
operators together
so you can minimize the number of similar HTTP requests
and consume network bandwidth economically.
You will add a heroes search feature to the Dashboard. As the user types a name into a search box, you'll make repeated HTTP requests for heroes filtered by that name. Your goal is to issue only as many requests as necessary.
HeroService.searchHeroes
Start by adding a searchHeroes
method to the HeroService
.
The method returns immediately with an empty array if there is no search term.
The rest of it closely resembles getHeroes()
.
The only significant difference is the URL,
which includes a query string with the search term.
Add search to the Dashboard
Open the DashboardComponent
template and
Add the hero search element, <app-hero-search>
, to the bottom of the DashboardComponent
template.
This template looks a lot like the *ngFor
repeater in the HeroesComponent
template.
Unfortunately, adding this element breaks the app.
Angular can't find a component with a selector that matches <app-hero-search>
.
The HeroSearchComponent
doesn't exist yet. Fix that.
Create HeroSearchComponent
Create a HeroSearchComponent
with the CLI.
The CLI generates the three HeroSearchComponent
and adds the component to the `AppModule' declarations
Replace the generated HeroSearchComponent
template with a text box and a list of matching search results like this.
Add private CSS styles to hero-search.component.css
as listed in the final code review below.
As the user types in the search box, a keyup event binding calls the component's search()
method with the new search box value.
{@a asyncpipe}
AsyncPipe
As expected, the *ngFor
repeats hero objects.
Look closely and you'll see that the *ngFor
iterates over a list called heroes$
, not heroes
.
The $
is a convention that indicates heroes$
is an Observable
, not an array.
The *ngFor
can't do anything with an Observable
.
But there's also a pipe character (|
) followed by async
,
which identifies Angular's AsyncPipe
.
The AsyncPipe
subscribes to an Observable
automatically so you won't have to
do so in the component class.
Fix the HeroSearchComponent class
Replace the generated HeroSearchComponent
class and metadata as follows.
Notice the declaration of heroes$
as an Observable
You'll set it in ngOnInit()
.
Before you do, focus on the definition of searchTerms
.
The searchTerms RxJS subject
The searchTerms
property is declared as an RxJS Subject
.
A Subject
is both a source of observable values and an Observable
itself.
You can subscribe to a Subject
as you would any Observable
.
You can also push values into that Observable
by calling its next(value)
method
as the search()
method does.
The search()
method is called via an event binding to the
textbox's keystroke
event.
Every time the user types in the textbox, the binding calls search()
with the textbox value, a "search term".
The searchTerms
becomes an Observable
emitting a steady stream of search terms.
{@a search-pipe}
Chaining RxJS operators
Passing a new search term directly to the searchHeroes()
after every user keystroke would create an excessive amount of HTTP requests,
taxing server resources and burning through the cellular network data plan.
Instead, the ngOnInit()
method pipes the searchTerms
observable through a sequence of RxJS operators that reduce the number of calls to the searchHeroes()
,
ultimately returning an observable of timely hero search results (each a Hero[]
).
Here's the code.
-
debounceTime(300)
waits until the flow of new string events pauses for 300 milliseconds before passing along the latest string. You'll never make requests more frequently than 300ms. -
distinctUntilChanged()
ensures that a request is sent only if the filter text changed. -
switchMap()
calls the search service for each search term that makes it throughdebounce
anddistinctUntilChanged
. It cancels and discards previous search observables, returning only the latest search service observable.
With the switchMap operator,
every qualifying key event can trigger an HttpClient.get()
method call.
Even with a 300ms pause between requests, you could have multiple HTTP requests in flight
and they may not return in the order sent.
switchMap()
preserves the original request order while returning only the observable from the most recent HTTP method call.
Results from prior calls are canceled and discarded.
Note that canceling a previous searchHeroes()
Observable
doesn't actually abort a pending HTTP request.
Unwanted results are simply discarded before they reach your application code.
Remember that the component class does not subscribe to the heroes$
observable.
That's the job of the AsyncPipe
in the template.
Try it
Run the app again. In the Dashboard, enter some text in the search box. If you enter characters that match any existing hero names, you'll see something like this.
Final code review
Your app should look like this .
Here are the code files discussed on this page (all in the src/app/
folder).
{@a heroservice} {@a inmemorydataservice} {@a appmodule}
HeroService, InMemoryDataService, AppModule
{@a heroescomponent}
HeroesComponent
{@a herodetailcomponent}
HeroDetailComponent
{@a herosearchcomponent}
HeroSearchComponent
Summary
You're at the end of your journey, and you've accomplished a lot.
- You added the necessary dependencies to use HTTP in the app.
- You refactored
HeroService
to load heroes from a web API. - You extended
HeroService
to supportpost()
,put()
, anddelete()
methods. - You updated the components to allow adding, editing, and deleting of heroes.
- You configured an in-memory web API.
- You learned how to use observables.
This concludes the "Tour of Heroes" tutorial. You're ready to learn more about Angular development in the fundamentals section, starting with the Architecture guide.