87
Reactor of Java 这一章来自于《Spring in Action, 5th》 的笔记,因为这本书讲Reactor of Java讲的太好了,所以作为笔记摘抄了下来。
Reactor of Java
In an imperative programming model, the code would look something like this:
String name = “Craig”;
String capitalName = name.toUpperCase();
String greeting = "Hello, " + capitalName + “!”;
System.out.println(greeting);
In the imperative model, each line of code performs a step, one right after the other, and definitely in the same thread. Each step blocks the executing thread from moving to the next step until complete. In contrast, functional, reactive code could achieve the same thing like this:
Mono.just(“Craig”)
.map(n -> n.toUpperCase())
.map(n -> “Hello, " + n + " !”)
.subscribe(System.out::println);
The Mono in the example is one of Reactor’s two core types. Flux is the other. Both are implementations of Reactive Streams’ Publisher.
A Flux represents** a pipeline of zero, one, or many (potentially infinite) data items**.
A Mono is a specialized reactive type that’s optimized for when the dataset is known to have no more than one data item.
CREATING FROM OBJECTS
Flux fruitFlux = Flux
.just(“Apple”, “Orange”, “Grape”, “Banana”, “Strawberry”);
fruitFlux.subscribe(f -> System.out.println("Hello " + f));
// for test
StepVerifier.create(fruitFlux)
.expectNext(“Apple”)
.expectNext(“Orange”)
.expectNext(“Grape”)
.expectNext(“Banana”)
.expectNext(“Strawberry”)
.verifyComplete();
CREATING FROM COLLECTIONS
Stream fruitStream = Stream.of(“Apple”, “Orange”, “Grape”, “Banana”, “Strawberry”);
Flux fruitFlux2 = Flux.fromStream(fruitStream);
fruitFlux2.subscribe(s -> System.out.println(s));
List<String> fruitList = new ArrayList<>();
fruitList.add("Apple");
fruitList.add("Orange");
fruitList.add("Grape");
fruitList.add("Banana");
fruitList.add("Strawberry");
Flux<String> fruitFlux3 = Flux.fromIterable(fruitList);
fruitFlux3.subscribe(s -> System.out.println(s));
String[] fruits = new String[] {"Apple", "Orange", "Grape", "Banana", "Strawberry" };
Flux<String> fruitFlux = Flux.fromArray(fruits);
fruitFlux.subscribe(s -> System.out.println(s));
StepVerifier.create(fruitFlux)
.expectNext("Apple")
.expectNext("Orange")
.expectNext("Grape")
.expectNext("Banana")
.expectNext("Strawberry")
.verifyComplete();
- 1
- 2
- 3
- 4
- 5
- 6
- 7
- 8
- 9
- 10
- 11
- 12
- 13
- 14
- 15
- 16
- 17
- 18
- 19
- 20
GENERATING FLUX DATA
Flux intervalFlux =
Flux.range(1, 5);
intervalFlux.subscribe(integer -> System.out.println(integer));
StepVerifier.create(intervalFlux)
.expectNext(1)
.expectNext(2)
.expectNext(3)
.expectNext(4)
.expectNext(5)
.verifyComplete();
Flux intervalFlux =
Flux.interval(Duration.ofSeconds(1))
.take(5);
intervalFlux.subscribe(i -> System.out.println(i));
StepVerifier.create(intervalFlux)
.expectNext(0L)
.expectNext(1L)
.expectNext(2L)
.expectNext(3L)
.expectNext(4L)
.verifyComplete();
MERGING REACTIVE TYPES
Flux characterFlux = Flux
.just(“Garfield”, “Kojak”, “Barbossa”)
.delayElements(Duration.ofMillis(500));
Flux foodFlux = Flux
.just(“Lasagna”, “Lollipops”, “Apples”)
.delaySubscription(Duration.ofMillis(250))
.delayElements(Duration.ofMillis(500));
Flux mergedFlux = characterFlux.mergeWith(foodFlux);
mergedFlux.subscribe(s -> System.out.println(s));
StepVerifier.create(mergedFlux)
.expectNext(“Garfield”)
.expectNext(“Lasagna”)
.expectNext(“Kojak”)
.expectNext(“Lollipops”)
.expectNext(“Barbossa”)
.expectNext(“Apples”)
.verifyComplete();
Flux characterFlux = Flux
.just(“Garfield”, “Kojak”, “Barbossa”);
Flux foodFlux = Flux
.just(“Lasagna”, “Lollipops”, “Apples”);
Flux<Tuple2<String, String>> zippedFlux =
Flux.zip(characterFlux, foodFlux);
zippedFlux.subscribe(x -> System.out.println(x));
StepVerifier.create(zippedFlux)
.expectNextMatches(p ->
p.getT1().equals(“Garfield”) &&
p.getT2().equals(“Lasagna”))
.expectNextMatches(p ->
p.getT1().equals(“Kojak”) &&
p.getT2().equals(“Lollipops”))
.expectNextMatches(p ->
p.getT1().equals(“Barbossa”) &&
p.getT2().equals(“Apples”))
.verifyComplete();
Flux characterFlux = Flux
.just(“Garfield”, “Kojak”, “Barbossa”);
Flux foodFlux = Flux
.just(“Lasagna”, “Lollipops”, “Apples”);
Flux zippedFlux =
Flux.zip(characterFlux, foodFlux, (c, f) -> c + " eats " + f);
zippedFlux.subscribe(x -> System.out.println(x));
StepVerifier.create(zippedFlux)
.expectNext(“Garfield eats Lasagna”)
.expectNext(“Kojak eats Lollipops”)
.expectNext(“Barbossa eats Apples”)
.verifyComplete();
SELECTING THE FIRST REACTIVE TYPE TO PUBLISH
Flux slowFlux = Flux.just(“tortoise”, “snail”, “sloth”)
.delaySubscription(Duration.ofMillis(100));
Flux fastFlux = Flux.just(“hare”, “cheetah”, “squirrel”);
Flux firstFlux = Flux.first(slowFlux, fastFlux);
StepVerifier.create(firstFlux)
.expectNext(“hare”)
.expectNext(“cheetah”)
.expectNext(“squirrel”)
.verifyComplete();
FILTERING DATA FROM REACTIVE TYPES
Flux skipFlux = Flux.just(
“one”, “two”, “skip a few”, “ninety nine”, “one hundred”)
.skip(3);
StepVerifier.create(skipFlux)
.expectNext(“ninety nine”, “one hundred”)
.verifyComplete();
Flux skipFlux = Flux.just(
“one”, “two”, “skip a few”, “ninety nine”, “one hundred”)
.delayElements(Duration.ofSeconds(1))
.skip(Duration.ofSeconds(4));
StepVerifier.create(skipFlux)
.expectNext(“ninety nine”, “one hundred”)
.verifyComplete();
Flux nationalParkFlux = Flux.just(
“Yellowstone”, “Yosemite”, “Grand Canyon”,
“Zion”, “Grand Teton”)
.take(3);
StepVerifier.create(nationalParkFlux)
.expectNext(“Yellowstone”, “Yosemite”, “Grand Canyon”)
.verifyComplete();
Flux nationalParkFlux = Flux.just(
“Yellowstone”, “Yosemite”, “Grand Canyon”,
“Zion”, “Grand Teton”)
.delayElements(Duration.ofSeconds(1))
.take(Duration.ofMillis(3500));
StepVerifier.create(nationalParkFlux)
.expectNext(“Yellowstone”, “Yosemite”, “Grand Canyon”)
.verifyComplete();
Flux nationalParkFlux = Flux.just(
“Yellowstone”, “Yosemite”, “Grand Canyon”,
“Zion”, “Grand Teton”)
.filter(np -> !np.contains(" "));
StepVerifier.create(nationalParkFlux)
.expectNext(“Yellowstone”, “Yosemite”, “Zion”)
.verifyComplete();
Flux animalFlux = Flux.just(
“dog”, “cat”, “bird”, “dog”, “bird”, “anteater”)
.distinct();
StepVerifier.create(animalFlux)
.expectNext(“dog”, “cat”, “bird”, “anteater”)
.verifyComplete();
MAPPING REACTIVE DATA
Flux playerFlux = Flux
.just(“Michael Jordan”, “Scottie Pippen”, “Steve Kerr”)
.map(n -> {
String[] split = n.split("\s");
return new Player(split[0], split[1]);
});
StepVerifier.create(playerFlux)
.expectNext(new Player(“Michael”, “Jordan”))
.expectNext(new Player(“Scottie”, “Pippen”))
.expectNext(new Player(“Steve”, “Kerr”))
.verifyComplete();
Flux playerFlux = Flux
.just(“Michael Jordan”, “Scottie Pippen”, “Steve Kerr”)
.flatMap(n -> Mono.just(n)
.map(p -> {
String[] split = p.split("\s");
return new Player(split[0], split[1]);
})
.subscribeOn(Schedulers.parallel())
);
List playerList = Arrays.asList(
new Player(“Michael”, “Jordan”),
new Player(“Scottie”, “Pippen”),
new Player(“Steve”, “Kerr”));
StepVerifier.create(playerFlux)
.expectNextMatches(p -> playerList.contains§)
.expectNextMatches(p -> playerList.contains§)
.expectNextMatches(p -> playerList.contains§)
.verifyComplete();
BUFFERING DATA ON A REACTIVE STREAM
Flux fruitFlux = Flux.just(
“apple”, “orange”, “banana”, “kiwi”, “strawberry”);
Flux<List> bufferedFlux = fruitFlux.buffer(3);
StepVerifier
.create(bufferedFlux)
.expectNext(Arrays.asList(“apple”, “orange”, “banana”))
.expectNext(Arrays.asList(“kiwi”, “strawberry”))
.verifyComplete();
Buffering values from a reactive Flux into non-reactive List collections seems counterproductive. But when you combine buffer() with flatMap(), it enables each of the List collections to be processed in parallel:
Flux.just(
“apple”, “orange”, “banana”, “kiwi”, “strawberry”)
.buffer(3)
.flatMap(x ->
Flux.fromIterable(x)
.map(y -> y.toUpperCase())
.subscribeOn(Schedulers.parallel())
.log()
).subscribe();
Flux fruitFlux = Flux.just(
“apple”, “orange”, “banana”, “kiwi”, “strawberry”);
Mono<List> fruitListMono = fruitFlux.collectList();
StepVerifier
.create(fruitListMono)
.expectNext(Arrays.asList(
“apple”, “orange”, “banana”, “kiwi”, “strawberry”))
.verifyComplete();
Flux animalFlux = Flux.just(
“aardvark”, “elephant”, “koala”, “eagle”, “kangaroo”);
Mono<Map<Character, String>> animalMapMono =
animalFlux.collectMap(a -> a.charAt(0));
StepVerifier
.create(animalMapMono)
.expectNextMatches(map -> {
return
map.size() == 3 &&
map.get(‘a’).equals(“aardvark”) &&
map.get(‘e’).equals(“eagle”) &&
map.get(‘k’).equals(“kangaroo”);
})
.verifyComplete();
Performing logic operations on reactive types
Flux animalFlux = Flux.just(
“aardvark”, “elephant”, “koala”, “eagle”, “kangaroo”);
Mono hasAMono = animalFlux.all(a -> a.contains(“a”));
StepVerifier.create(hasAMono)
.expectNext(true)
.verifyComplete();
Mono hasKMono = animalFlux.all(a -> a.contains(“k”));
StepVerifier.create(hasKMono)
.expectNext(false)
.verifyComplete();
Flux animalFlux = Flux.just(
“aardvark”, “elephant”, “koala”, “eagle”, “kangaroo”);
Mono hasAMono = animalFlux.any(a -> a.contains(“a”));
StepVerifier.create(hasAMono)
.expectNext(true)
.verifyComplete();
Mono hasZMono = animalFlux.any(a -> a.contains(“z”));
StepVerifier.create(hasZMono)
.expectNext(false)
.verifyComplete();
Spring MVC change to Spring WebFlux
@GetMapping("/recent")
public Iterable recentTacos() {
PageRequest page = PageRequest.of(
0, 12, Sort.by(“createdAt”).descending());
return tacoRepo.findAll(page).getContent();
}
@GetMapping("/recent")
public Flux recentTacos() {
return Flux.fromIterable(tacoRepo.findAll()).take(12);
}
@PostMapping(consumes=“application/json”)
@ResponseStatus(HttpStatus.CREATED)
public Taco postTaco(@RequestBody Taco taco) {
return tacoRepo.save(taco);
}
@PostMapping(consumes=“application/json”)
@ResponseStatus(HttpStatus.CREATED)
public Mono postTaco(@RequestBody Mono tacoMono) {
return tacoRepo.saveAll(tacoMono).next();
}
public interface TacoRepository
extends ReactiveCrudRepository<Taco, Long> {
}
@GetMapping("/{id}")
public Taco tacoById(@PathVariable(“id”) Long id) {
Optional optTaco = tacoRepo.findById(id);
if (optTaco.isPresent()) {
return optTaco.get();
}
return null;
}
@GetMapping("/{id}")
public Mono tacoById(@PathVariable(“id”) Long id) {
return tacoRepo.findById(id);
}
WORKING WITH RXJAVA TYPES
@GetMapping("/recent")
public Observable recentTacos() {
return tacoService.getRecentTacos();
}
@GetMapping("/{id}")
public Single tacoById(@PathVariable(“id”) Long id) {
return tacoService.lookupTaco(id);
}
Developing Reactive APIs
@Configuration
public class RouterFunctionConfig {
@Autowired
private TacoRepository tacoRepo;
@Bean
public RouterFunction<?> routerFunction() {
return route(GET("/design/taco"), this::recents)
Testing reactive controllers 279
.andRoute(POST("/design"), this::postTaco);
}
public Mono recents(ServerRequest request) {
return ServerResponse.ok()
.body(tacoRepo.findAll().take(12), Taco.class);
}
public Mono postTaco(ServerRequest request) {
Mono taco = request.bodyToMono(Taco.class);
Mono savedTaco = tacoRepo.save(taco);
return ServerResponse
.created(URI.create(
“http://localhost:8080/design/taco/” +
savedTaco.getId()))
.body(savedTaco, Taco.class);
}
}
Test Reactive Rest APIs
// Test Get Method
Taco[] tacos = {
testTaco(1L), testTaco(2L),
testTaco(3L), testTaco(4L),
testTaco(5L), testTaco(6L),
testTaco(7L), testTaco(8L),
testTaco(9L), testTaco(10L),
testTaco(11L), testTaco(12L),
testTaco(13L), testTaco(14L),
testTaco(15L), testTaco(16L)};
Flux tacoFlux = Flux.just(tacos);
TacoRepository tacoRepo = Mockito.mock(TacoRepository.class);
when(tacoRepo.findAll()).thenReturn(tacoFlux);
WebTestClient testClient = WebTestClient.bindToController(
new DesignTacoController(tacoRepo))
.build();
testClient.get().uri("/design/recent")
.exchange()
.expectStatus().isOk()
.expectBody()
.jsonPath("" ) . i s A r r a y ( ) . j s o n P a t h ( " ").isArray() .jsonPath("").isArray().jsonPath("").isNotEmpty()
.jsonPath("[ 0 ] . i d " ) . i s E q u a l T o ( t a c o s [ 0 ] . g e t I d ( ) . t o S t r i n g ( ) ) . j s o n P a t h ( " [0].id").isEqualTo(tacos[0].getId().toString()) .jsonPath("[0].id").isEqualTo(tacos[0].getId().toString()).jsonPath("[0].name").isEqualTo(“Taco 1”).jsonPath("[ 1 ] . i d " ) . i s E q u a l T o ( t a c o s [ 1 ] . g e t I d ( ) . t o S t r i n g ( ) ) . j s o n P a t h ( " [1].id") .isEqualTo(tacos[1].getId().toString()).jsonPath("[1].id").isEqualTo(tacos[1].getId().toString()).jsonPath("[1].name")
.isEqualTo(“Taco 2”).jsonPath("[ 11 ] . i d " ) . i s E q u a l T o ( t a c o s [ 11 ] . g e t I d ( ) . t o S t r i n g ( ) ) . j s o n P a t h ( " [11].id") .isEqualTo(tacos[11].getId().toString()) .jsonPath("[11].id").isEqualTo(tacos[11].getId().toString()).jsonPath("[11].name").isEqualTo(“Taco 12”).jsonPath("[ 12 ] " ) . d o e s N o t E x i s t ( ) . j s o n P a t h ( " [12]") .doesNotExist().jsonPath("[12]").doesNotEx