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Spring Boot is a project that is built on the top of the Spring Framework.
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It provides an easier and faster way to set up, configure, and run both simple and web-based applications.
We should use Spring Boot Framework because:
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The dependency injection approach is used in Spring Boot.
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It contains powerful database transaction management capabilities.
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It simplifies integration with other Java frameworks like JPA/Hibernate ORM, Struts, etc.
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It reduces the cost and development time of the application.
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Along with the Spring Boot Framework, many other Spring sister projects help to build applications addressing modern business needs.
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Spring Data: It simplifies data access from the relational and NoSQL databases.
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Spring Batch: It provides powerful batch processing.
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Spring Security: It is a security framework that provides robust security to applications.
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Spring Social: It supports integration with social networking like LinkedIn.
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Spring Integration: It is an implementation of Enterprise Integration Patterns.
It facilitates integration with other enterprise applications using lightweight messaging and declarative adapters.
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It creates stand-alone Spring applications that can be started using Java -jar.
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It tests web applications easily with the help of different Embedded HTTP servers such as Tomcat, Jetty, etc. We don't need to deploy WAR files.
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It provides opinionated 'starter' POMs to simplify our Maven configuration.
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It provides production-ready features such as metrics, health checks, and externalized configuration.
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There is no requirement for XML configuration.
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It offers a CLI tool for developing and testing the Spring Boot application.
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It offers the number of plug-ins.
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It also minimizes writing multiple boilerplate codes (the code that has to be included in many places with little or no alteration), XML configuration, and annotations.
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It increases productivity and reduces development time.
Spring Boot can use dependencies that are not going to be used in the application. These dependencies increase the size of the application.
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Web Development
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SpringApplication
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Application events and listeners
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Admin features
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Externalized Configuration
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Properties Files
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YAML Support
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Type-safe Configuration
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Logging
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Security
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@Required: It applies to the bean setter method. It indicates that the annotated bean must be populated at configuration time with the required property, else it throws an exception BeanInitilizationException.
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@Autowired: Spring provides annotation-based auto-wiring by providing @Autowired annotation. It is used to autowire spring bean on setter methods, instance variable, and constructor. When we use @Autowired annotation, the spring container auto-wires the bean by matching data-type.
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@Configuration: It is a class-level annotation. The class annotated with @Configuration used by Spring Containers as a source of bean definitions.
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@ComponentScan: It is used when we want to scan a package for beans. It is used with the annotation @Configuration. We can also specify the base packages to scan for Spring Components.
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@Bean: It is a method-level annotation. It is an alternative of XML tag. It tells the method to produce a bean to be managed by Spring Container.
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@Component: It is a class-level annotation. It is used to mark a Java class as a bean. A Java class annotated with @Component is found during the classpath. The Spring Framework pick it up and configure it in the application context as a Spring Bean.
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@Controller: The @Controller is a class-level annotation. It is a specialization of @Component. It marks a class as a web request handler. It is often used to serve web pages. By default, it returns a string that indicates which route to redirect. It is mostly used with @RequestMapping annotation.
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@Service: It is also used at class level. It tells the Spring that class contains the business logic.
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@Repository: It is a class-level annotation. The repository is a DAOs (Data Access Object) that access the database directly. The repository does all the operations related to the database.
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@SpringBootApplication: It is a combination of three annotations @EnableAutoConfiguration, @ComponentScan, and @Configuration.
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@RequestMapping: It is used to map the web requests. It has many optional elements like consumes, header, method, name, params, path, produces, and value. We use it with the class as well as the method.
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@GetMapping: It maps the HTTP GET requests on the specific handler method. It is used to create a web service endpoint that fetches It is used instead of using: @RequestMapping(method = RequestMethod.GET)
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@PostMapping: It maps the HTTP POST requests on the specific handler method. It is used to create a web service endpoint that creates It is used instead of using: @RequestMapping(method = RequestMethod.POST)
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@PutMapping: It maps the HTTP PUT requests on the specific handler method. It is used to create a web service endpoint that creates or updates It is used instead of using: @RequestMapping(method = RequestMethod.PUT)
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@DeleteMapping: It maps the HTTP DELETE requests on the specific handler method. It is used to create a web service endpoint that deletes a resource. It is used instead of using: @RequestMapping(method = RequestMethod.DELETE)
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@PatchMapping: It maps the HTTP PATCH requests on the specific handler method. It is used instead of using: @RequestMapping(method = RequestMethod.PATCH)
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@RequestBody: It is used to bind HTTP request with an object in a method parameter. Internally it uses HTTP MessageConverters to convert the body of the request. When we annotate a method parameter with @RequestBody, the Spring framework binds the incoming HTTP request body to that parameter.
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@ResponseBody: It binds the method return value to the response body. It tells the Spring Boot Framework to serialize a return an object into JSON and XML format.
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@PathVariable: It is used to extract the values from the URI. It is most suitable for the RESTful web service, where the URL contains a path variable. We can define multiple @PathVariable in a method.
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@RequestParam: It is used to extract the query parameters form the URL. It is also known as a query parameter. It is most suitable for web applications. It can specify default values if the query parameter is not present in the URL.
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@RequestHeader: It is used to get the details about the HTTP request headers. We use this annotation as a method parameter. The optional elements of the annotation are name, required, value, defaultValue. For each detail in the header, we should specify separate annotations. We can use it multiple time in a method
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@RestController: It can be considered as a combination of @Controller and @ResponseBody annotations. The @RestController annotation is itself annotated with the @ResponseBody annotation. It eliminates the need for annotating each method with @ResponseBody.
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@RequestAttribute: It binds a method parameter to request attribute. It provides convenient access to the request attributes from a controller method. With the help of @RequestAttribute annotation, we can access objects that are populated on the server-side.
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@EnableSwagger2: Mainly used for documentation the Restful we-service
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@EnableOAuth2Sso: Oauth Authentication
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internal Logger -> Apache Commons Logging
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private final Logger LOGGER = LoggerFactory.getLogger(this.getClass());
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spring.output.ansi.enabled - always, detect or never
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LOGGER.info("Simple log statement with inputs {}, {} and {}", 1,2,3);
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Types -> logging, log4j, logback
LOGGER.debug("This is a debug message"); LOGGER.info("This is an info message"); LOGGER.warn("This is a warn message"); LOGGER.error("This is an error message");
@AssertFalse -> The annotated element must be false.
@AssertTrue -> The annotated element must be true.
@DecimalMax -> The annotated element must be a number whose value must be lower or equal to the specified maximum.
@DecimalMin -> The annotated element must be a number whose value must be higher or equal to the specified minimum.
@Future -> The annotated element must be an instant, date or time in the future.
@Max -> The annotated element must be a number whose value must be lower or equal to the specified maximum.
@Min -> The annotated element must be a number whose value must be higher or equal to the specified minimum.
@Negative -> The annotated element must be a strictly negative number.
@NotBlank -> The annotated element must not be null and must contain at least one non-whitespace character.
@NotEmpty -> The annotated element must not be null nor empty.
@NotNull -> The annotated element must not be null.
@Null -> The annotated element must be null.
@Pattern -> The annotated CharSequence must match the specified regular expression.
@Positive -> The annotated element must be a strictly positive number.
@Size -> The annotated element size must be between the specified boundaries (included).
* @Before: declares the before advice. It is applied before calling the actual method.
* @After: declares the after advice. It is applied after calling the actual method and before returning result.
* @AfterReturning: declares the after returning advice. It is applied after calling the actual method and before returning result.
* @Around: declares the around advice. It is applied before and after calling the actual method.
* @AfterThrowing: declares the throws advice. It is applied if actual method throws exception.
* @BeforeClass
* @Before
* @Test
* @After
* @AfterClass
Void equals(boolean exptation, boolean Actual)
Void Notequals(boolean exptation, boolean Actual)
Void assertTrue(boolean condition)
Void assertFalse(boolean condition)
Void assertNull(Object object)
Void assertNotNull(Object object)
Void assertSame(Object object1,Object object 2)
Void assertNotSame(Object object1,Object object 2)
void assertArrayEquals(expectedArray, resultArray);
*Project Lombok is a Java library tool that generates code for minimizing boilerplate code.
*The library replaces boilerplate code with easy-to-use annotations.
* Will add all getter and setters
* To string
* Equal and barcode
```
var and val
@Getter, @Setter
@NoArgsConstructor, @AllArgsConstructor
@Data
@NotNull
```
* request
* response
* get
* post
* jsp
* jstl
* bootstrap
* dispatcher servlet
* view resolver
* model
* view
* validation
* form tags
* starterss
* Autoconfiguration
* Initializr
* actuator
* embedded servers
- Collection of small autonomous
- Small multiple services
- All component seperate module
- Stateless communication
- easy to maintain
- Continuous Delivery
- Hybrid Technology -java csharp mysql
- Cross Team coordination
- Higher Quality code
- Smarter Scaling
- Risk Reduction -Seperation of services allowed for localized changes
- Promote Big Data Best Practises
- Improved ROI with Reduced TCO
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Client Side load balancer - Ribbon
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Distributed Tracking - Sluth and Zipkin
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Fault Tolerance using Hystrix
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Feign Client
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Router and ZUUL
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Service Registry using Eureka
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Spring Cloud BUS
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Spring Cloud Config
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Codebase = One codebase tracked in revision control, many deploys - SVN
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Dependencies = Explicitly declare and isolate dependencies - pom.xml
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Config = Store config in the environment - DEV ,FET , ACC
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Backing services = Treat backing services as attached resources
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Build, release, run = Strictly separate build and run stages
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Processes = Execute the app as one or more stateless processes
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Port binding = Export services via port binding
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Concurrency = Scale out via the process model
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Disposability = Maximize robustness with fast startup and graceful shutdown
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Dev/prod parity = Keep development, staging, and production as similar as possibe
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Logs = Treat logs as event streams
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Admin processes = Run admin/management tasks as one-off processes
The application.properties file allows us to run an application in a different environment. In short, we can use the application.properties file to:
* Configure the Spring Boot framework
* define our application custom configuration properties
There are sixteen categories of Spring Boot Property are as follows:
Core Properties
Cache Properties
Mail Properties
JSON Properties
Data Properties
Transaction Properties
Data Migration Properties
Integration Properties
Web Properties
Templating Properties
Server Properties
Security Properties
RSocket Properties
Actuator Properties
DevTools Properties
Testing Properties
#MYSQL DB Properties
spring.datasource.driver-class-name=com.mysql.cj.jdbc.Driver
spring.datasource.url=jdbc:mysql://localhost:3306/dbname
spring.datasource.username=root
spring.datasource.password=root
#JPA Properties
spring.jpa.hibernate.ddl-auto=update
spring.jpa.generate-ddl=true
spring.jpa.show-sql=true
spring.jpa.properties.hibernate.format_sql=true
#Eureka Properties
eureka.client.register-with-eureka=true
eureka.client.fetch-registry=true
eureak.instance.hostnam=localhost
management.endpoints.web.exposure.include=*
eureka.client.serviceUrl.defaultZone = http://localhost:8761/eureka
spring.cloud.config.uri=http://localhost:8888
spring.rabbitmq.addresses=amqps://ailhzrhf:pnHKsJmZxwUZwUh_P7wEBiiD37BrfCnQ@finch.rmq.cloudamqp.com/ailhzrhf
Server:
Jetty
Spring jpa mysql security
security:
oauth2:
client:
clientId: a48f56f893775afb1912
clientSecret: c91036f105c04d0666655f411f716c43b606d373
accessTokenUri: https://github.com/login/oauth/access_token
userAuthorizationUri: https://github.com/login/oauth/authorize
clientAuthenticationScheme: form
resource:
user-info-uri: https://api.github.com/user
prefer-token-info: false
DevTools stands for Developer Tool. The aim of the module is to try and improve the development time while working with the Spring Boot application.
Spring Boot DevTools pick up the changes and restart the application.
We can implement the DevTools in our project by adding the following dependency in the pom.xml file.
<dependency>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-devtools</artifactId>
<scope>runtime<scope >
</dependency>
* Property Defaults
* Automatic Restart
* LiveReload
* Remote Debug Tunneling
* Remote Update and Restart
/META-INF/maven
/META-INF/resources
/resources
/static
/public
/templates
N-Tier and monolithic applications used to be the de facto standard. In one single binary web artifact, like an EAR or WAR file, there would be a layered architecture with the decomposition of code into more functional components.
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Presentation Layer
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Business Process Layer/Service Layer
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Data Access Layer
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Tight coupling of code which makes changes hard.
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A single deployment with multiple layers that causes long testing, building, and deployment cycles.
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A big monolithic application that makes code reuse and sharing of components difficult.
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The Microservices Architecture (MSA) decomposes systems into discrete, individual, standalone components that can communicate amongst themselves, working together or with external systems.
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MSA is a more agile framework that fits well with the cloud-based world and lends itself well to web application development and web service development.
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MSA is very flexible because it supports any language that can communicate via a RESTful endpoint and leverages REST over HTTP.
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MSA offers agility and systems that are easier to write, test, deploy, and share.
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MSA provides systems that can better scale to load and demand.
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MSA provides systems that are resilient because failures are isolated and don’t cascade through the infrastructure.
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Eureka, created by Netflix, is responsible for the registration and discovery microservices. Spring has incorporated Eureka into Spring Cloud, making it even easier to stand up a Eureka server.
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Eureka consists of a server and a client-side component. The server component will be the registry in which all the microservices register their availability. The microservices use the Eureka client to register; once the registration is complete, it notifies the server of its existence.
A microservice must register itself with a discovery service
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spring cloud starter config
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spring cloud netfli eureka server
javax.xml.bind jaxb-api 2.4.0-b180725.0427
spring.appliation.name=eurela-server
server.port=8761
#dont register itself as client
eureka.client.regiser-with-eureka = false
eureka.client.fetch-registry= false
logging.level.com.netflix.eureka=ON
logging.level.com.netflix.discovery = ON
@SpringBootApplication
@EnableEurekaServer
https://localhost:8761
- system status
- current time -> uptime
- general Info -> total memory, enviroment, cpus
- DS replicas instane currently registered with Eureka
Spring Data REST builds on top of Spring Data repositories and automatically exports those as REST resources.
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At application startup, Spring Data Rest finds all of the spring data repositories
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Then, Spring Data Rest creates an endpoint that matches the entity name
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Next, Spring Data Rest appends an S to the entity name in the endpoint
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Lastly, Spring Data Rest exposes CRUD (Create, Read, Update, and Delete) operations as RESTful APIs over HTTP
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There is no need to create a controller or service layer!
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spring data
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JPA Item Repository
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Spring DATA REST
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For a @SpringBootApplication to be discovery-aware, all that's needed is the Spring Discovery Client (i.e., spring-cloud-starter-netflix-eureka-client dependency) in the classpath.
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The next step is to annotate the main Spring application class with the @EnableEurekaClient annotation.
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@EnableEurekaClient is optional if the spring-cloud-starter-netflix-eureka-client dependency is on the classpath.
HTTP defines these standard status codes that can be used to convey the results of a client’s request. The status codes are divided into five categories.
1xx: Informational – Communicates transfer protocol-level information.
2xx: Success – Indicates that the client’s request was accepted successfully.
3xx: Redirection – Indicates that the client must take some additional action in order to complete their request.
4xx: Client Error – This category of error status codes points the finger at clients.
5xx: Server Error – The server takes responsibility for these error status codes.
One application can expose its functionality as RESTful web services, which can be consumed by the other application using Spring's RestTemplate or WebClient.
Applications can use a messaging system such as Apache Kafka or RabbitMQ to send and receive messages. Spring provides support for both of these systems through the Spring Kafka and Spring Rabbit projects.
One application can use the Feign client to make remote calls to the other application. Feign is a declarative web service client and can be used to communicate between applications using HTTP.
Applications can use gRPC to communicate with each other. gRPC is a high-performance, open-source framework for building remote procedure call (RPC) APIs. Spring provides support for gRPC through the Spring gRPC project.
Applications can share data through a shared database or a data cache such as Redis or memcached. Spring provides support for various data sharing options through its Spring Data project.
Spring Cloud provides a way to register and discover microservices, one application can use service discovery to communicate with the other application.
It's depend on your requirement which one you want to use for communication between two spring boot application.
Package Details:
* ACEFMRSHWU
* Config | Controller | Exception | Filters | Model | Repository | Headers | Resources | Security | Auth | Util | Webservice | Model | WSDL