Feign is a Java to HTTP client binder inspired by Retrofit, JAXRS-2.0, and WebSocket. Feign's first goal was reducing the complexity of binding Denominator uniformly to HTTP APIs regardless of ReSTfulness.
Feign uses tools like Jersey and CXF to write java clients for ReST or SOAP services. Furthermore, Feign allows you to write your own code on top of http libraries such as Apache HC. Feign connects your code to http APIs with minimal overhead and code via customizable decoders and error handling, which can be written to any text-based http API.
Feign works by processing annotations into a templatized request. Arguments are applied to these templates in a straightforward fashion before output. Although Feign is limited to supporting text-based APIs, it dramatically simplifies system aspects such as replaying requests. Furthermore, Feign makes it easy to unit test your conversions knowing this.
Feign 10.x and above are built on Java 8 and should work on Java 9, 10, and 11. For those that need JDK 6 compatibility, please use Feign 9.x
This is a map with current key features provided by feign:
Making API clients easier
- Response Caching
- Support caching of api responses. Allow for users to define under what conditions a response is eligible for caching and what type of caching mechanism should be used.
- Support in-memory caching and external cache implementations (EhCache, Google, Spring, etc...)
- Complete URI Template expression support
- Support level 1 through level 4 URI template expressions.
- Use URI Templates TCK to verify compliance.
Logger
API refactor- Refactor the
Logger
API to adhere closer to frameworks like SLF4J providing a common mental model for logging within Feign. This model will be used by Feign itself throughout and provide clearer direction on how theLogger
will be used.
- Refactor the
Retry
API refactor- Refactor the
Retry
API to support user-supplied conditions and better control over back-off policies. This may result in non-backward-compatible breaking changes
- Refactor the
- Async execution support via
CompletableFuture
- Allow for
Future
chaining and executor management for the request/response lifecycle. Implementation will require non-backward-compatible breaking changes. However this feature is required before Reactive execution can be considered.
- Allow for
- Reactive execution support via Reactive Streams
- For JDK 9+, consider a native implementation that uses
java.util.concurrent.Flow
. - Support for Project Reactor and RxJava 2+ implementations on JDK 8.
- For JDK 9+, consider a native implementation that uses
- Additional Circuit Breaker Support.
- Support additional Circuit Breaker implementations like Resilience4J and Spring Circuit Breaker
Usage typically looks like this, an adaptation of the canonical Retrofit sample.
interface GitHub {
@RequestLine("GET /repos/{owner}/{repo}/contributors")
List<Contributor> contributors(@Param("owner") String owner, @Param("repo") String repo);
@RequestLine("POST /repos/{owner}/{repo}/issues")
void createIssue(Issue issue, @Param("owner") String owner, @Param("repo") String repo);
}
public static class Contributor {
String login;
int contributions;
}
public static class Issue {
String title;
String body;
List<String> assignees;
int milestone;
List<String> labels;
}
public class MyApp {
public static void main(String... args) {
GitHub github = Feign.builder()
.decoder(new GsonDecoder())
.target(GitHub.class, "https://api.github.com");
// Fetch and print a list of the contributors to this library.
List<Contributor> contributors = github.contributors("OpenFeign", "feign");
for (Contributor contributor : contributors) {
System.out.println(contributor.login + " (" + contributor.contributions + ")");
}
}
}
Feign annotations define the Contract
between the interface and how the underlying client
should work. Feign's default contract defines the following annotations:
Annotation | Interface Target | Usage |
---|---|---|
@RequestLine |
Method | Defines the HttpMethod and UriTemplate for request. Expressions , values wrapped in curly-braces {expression} are resolved using their corresponding @Param annotated parameters. |
@Param |
Parameter | Defines a template variable, whose value will be used to resolve the corresponding template Expression , by name provided as annotation value. If value is missing it will try to get the name from bytecode method parameter name (if the code was compiled with -parameters flag). |
@Headers |
Method, Type | Defines a HeaderTemplate ; a variation on a UriTemplate . that uses @Param annotated values to resolve the corresponding Expressions . When used on a Type , the template will be applied to every request. When used on a Method , the template will apply only to the annotated method. |
@QueryMap |
Parameter | Defines a Map of name-value pairs, or POJO, to expand into a query string. |
@HeaderMap |
Parameter | Defines a Map of name-value pairs, to expand into Http Headers |
@Body |
Method | Defines a Template , similar to a UriTemplate and HeaderTemplate , that uses @Param annotated values to resolve the corresponding Expressions . |
Overriding the Request Line
If there is a need to target a request to a different host then the one supplied when the Feign client was created, or you want to supply a target host for each request, include a
java.net.URI
parameter and Feign will use that value as the request target.@RequestLine("POST /repos/{owner}/{repo}/issues") void createIssue(URI host, Issue issue, @Param("owner") String owner, @Param("repo") String repo);
Feign Expressions
represent Simple String Expressions (Level 1) as defined by URI Template - RFC 6570. Expressions
are expanded using
their corresponding Param
annotated method parameters.
Example
public interface GitHub {
@RequestLine("GET /repos/{owner}/{repo}/contributors")
List<Contributor> contributors(@Param("owner") String owner, @Param("repo") String repository);
class Contributor {
String login;
int contributions;
}
}
public class MyApp {
public static void main(String[] args) {
GitHub github = Feign.builder()
.decoder(new GsonDecoder())
.target(GitHub.class, "https://api.github.com");
/* The owner and repository parameters will be used to expand the owner and repo expressions
* defined in the RequestLine.
*
* the resulting uri will be https://api.github.com/repos/OpenFeign/feign/contributors
*/
github.contributors("OpenFeign", "feign");
}
}
Expressions must be enclosed in curly braces {}
and may contain regular expression patterns, separated by a colon :
to restrict
resolved values. Example owner
must be alphabetic. {owner:[a-zA-Z]*}
RequestLine
and QueryMap
templates follow the URI Template - RFC 6570 specification for Level 1 templates, which specifies the following:
- Unresolved expressions are omitted.
- All literals and variable values are pct-encoded, if not already encoded or marked
encoded
via a@Param
annotation.
We also have limited support for Level 3, Path Style Expressions, with the following restrictions:
- Maps and Lists are expanded by default.
- Only Single variable templates are supported.
Examples:
{;who} ;who=fred
{;half} ;half=50%25
{;empty} ;empty
{;list} ;list=red;list=green;list=blue
{;map} ;semi=%3B;dot=.;comma=%2C
public interface MatrixService {
@RequestLine("GET /repos{;owners}")
List<Contributor> contributors(@Param("owners") List<String> owners);
class Contributor {
String login;
int contributions;
}
}
If owners
in the above example is defined as Matt, Jeff, Susan
, the uri will expand to /repos;owners=Matt;owners=Jeff;owners=Susan
For more information see RFC 6570, Section 3.2.7
Undefined expressions are expressions where the value for the expression is an explicit null
or no value is provided.
Per URI Template - RFC 6570, it is possible to provide an empty value
for an expression. When Feign resolves an expression, it first determines if the value is defined, if it is then
the query parameter will remain. If the expression is undefined, the query parameter is removed. See below
for a complete breakdown.
Empty String
public void test() {
Map<String, Object> parameters = new LinkedHashMap<>();
parameters.put("param", "");
this.demoClient.test(parameters);
}
Result
http://localhost:8080/test?param=
Missing
public void test() {
Map<String, Object> parameters = new LinkedHashMap<>();
this.demoClient.test(parameters);
}
Result
http://localhost:8080/test
Undefined
public void test() {
Map<String, Object> parameters = new LinkedHashMap<>();
parameters.put("param", null);
this.demoClient.test(parameters);
}
Result
http://localhost:8080/test
See Advanced Usage for more examples.
What about slashes?
/
@RequestLine templates do not encode slash
/
characters by default. To change this behavior, set thedecodeSlash
property on the@RequestLine
tofalse
.
What about plus?
+
Per the URI specification, a
+
sign is allowed in both the path and query segments of a URI, however, handling of the symbol on the query can be inconsistent. In some legacy systems, the+
is equivalent to the a space. Feign takes the approach of modern systems, where a+
symbol should not represent a space and is explicitly encoded as%2B
when found on a query string.If you wish to use
+
as a space, then use the literalcharacter or encode the value directly as
%20
The @Param
annotation has an optional property expander
allowing for complete control over the individual parameter's expansion.
The expander
property must reference a class that implements the Expander
interface:
public interface Expander {
String expand(Object value);
}
The result of this method adheres to the same rules stated above. If the result is null
or an empty string,
the value is omitted. If the value is not pct-encoded, it will be. See Custom @Param Expansion for more examples.
Headers
and HeaderMap
templates follow the same rules as Request Parameter Expansion
with the following alterations:
- Unresolved expressions are omitted. If the result is an empty header value, the entire header is removed.
- No pct-encoding is performed.
See Headers for examples.
A Note on
@Param
parameters and their names:All expressions with the same name, regardless of their position on the
@RequestLine
,@QueryMap
,@BodyTemplate
, or@Headers
will resolve to the same value. In the following example, the value ofcontentType
, will be used to resolve both the header and path expression:public interface ContentService { @RequestLine("GET /api/documents/{contentType}") @Headers("Accept: {contentType}") String getDocumentByType(@Param("contentType") String type); }Keep this in mind when designing your interfaces.
Body
templates follow the same rules as Request Parameter Expansion
with the following alterations:
- Unresolved expressions are omitted.
- Expanded value will not be passed through an
Encoder
before being placed on the request body. - A
Content-Type
header must be specified. See Body Templates for examples.
Feign has several aspects that can be customized.
For simple cases, you can use Feign.builder()
to construct an API interface with your custom components.
For request setting, you can use options(Request.Options options)
on target()
to set connectTimeout, connectTimeoutUnit, readTimeout, readTimeoutUnit, followRedirects.
For example:
interface Bank {
@RequestLine("POST /account/{id}")
Account getAccountInfo(@Param("id") String id);
}
public class BankService {
public static void main(String[] args) {
Bank bank = Feign.builder()
.decoder(new AccountDecoder())
.options(new Request.Options(10, TimeUnit.SECONDS, 60, TimeUnit.SECONDS, true))
.target(Bank.class, "https://api.examplebank.com");
}
}
Feign can produce multiple api interfaces. These are defined as Target<T>
(default HardCodedTarget<T>
), which allow for dynamic discovery and decoration of requests prior to execution.
For example, the following pattern might decorate each request with the current url and auth token from the identity service.
public class CloudService {
public static void main(String[] args) {
CloudDNS cloudDNS = Feign.builder()
.target(new CloudIdentityTarget<CloudDNS>(user, apiKey));
}
class CloudIdentityTarget extends Target<CloudDNS> {
/* implementation of a Target */
}
}
Feign includes example GitHub and Wikipedia clients. The denominator project can also be scraped for Feign in practice. Particularly, look at its example daemon.
Feign intends to work well with other Open Source tools. Modules are welcome to integrate with your favorite projects!
Gson includes an encoder and decoder you can use with a JSON API.
Add GsonEncoder
and/or GsonDecoder
to your Feign.Builder
like so:
public class Example {
public static void main(String[] args) {
GsonCodec codec = new GsonCodec();
GitHub github = Feign.builder()
.encoder(new GsonEncoder())
.decoder(new GsonDecoder())
.target(GitHub.class, "https://api.github.com");
}
}
Jackson includes an encoder and decoder you can use with a JSON API.
Add JacksonEncoder
and/or JacksonDecoder
to your Feign.Builder
like so:
public class Example {
public static void main(String[] args) {
GitHub github = Feign.builder()
.encoder(new JacksonEncoder())
.decoder(new JacksonDecoder())
.target(GitHub.class, "https://api.github.com");
}
}
For the lighter weight Jackson Jr, use JacksonJrEncoder
and JacksonJrDecoder
from
the Jackson Jr Module.
SaxDecoder allows you to decode XML in a way that is compatible with normal JVM and also Android environments.
Here's an example of how to configure Sax response parsing:
public class Example {
public static void main(String[] args) {
Api api = Feign.builder()
.decoder(SAXDecoder.builder()
.registerContentHandler(UserIdHandler.class)
.build())
.target(Api.class, "https://apihost");
}
}
JAXB includes an encoder and decoder you can use with an XML API.
Add JAXBEncoder
and/or JAXBDecoder
to your Feign.Builder
like so:
public class Example {
public static void main(String[] args) {
Api api = Feign.builder()
.encoder(new JAXBEncoder())
.decoder(new JAXBDecoder())
.target(Api.class, "https://apihost");
}
}
JAXRSContract overrides annotation processing to instead use standard ones supplied by the JAX-RS specification. This is currently targeted at the 1.1 spec.
Here's the example above re-written to use JAX-RS:
interface GitHub {
@GET @Path("/repos/{owner}/{repo}/contributors")
List<Contributor> contributors(@PathParam("owner") String owner, @PathParam("repo") String repo);
}
public class Example {
public static void main(String[] args) {
GitHub github = Feign.builder()
.contract(new JAXRSContract())
.target(GitHub.class, "https://api.github.com");
}
}
OkHttpClient directs Feign's http requests to OkHttp, which enables SPDY and better network control.
To use OkHttp with Feign, add the OkHttp module to your classpath. Then, configure Feign to use the OkHttpClient:
public class Example {
public static void main(String[] args) {
GitHub github = Feign.builder()
.client(new OkHttpClient())
.target(GitHub.class, "https://api.github.com");
}
}
RibbonClient overrides URL resolution of Feign's client, adding smart routing and resiliency capabilities provided by Ribbon.
Integration requires you to pass your ribbon client name as the host part of the url, for example myAppProd
.
public class Example {
public static void main(String[] args) {
MyService api = Feign.builder()
.client(RibbonClient.create())
.target(MyService.class, "https://myAppProd");
}
}
Http2Client directs Feign's http requests to Java11 New HTTP/2 Client that implements HTTP/2.
To use New HTTP/2 Client with Feign, use Java SDK 11. Then, configure Feign to use the Http2Client:
GitHub github = Feign.builder()
.client(new Http2Client())
.target(GitHub.class, "https://api.github.com");
HystrixFeign configures circuit breaker support provided by Hystrix.
To use Hystrix with Feign, add the Hystrix module to your classpath. Then use the HystrixFeign
builder:
public class Example {
public static void main(String[] args) {
MyService api = HystrixFeign.builder().target(MyService.class, "https://myAppProd");
}
}
SOAP includes an encoder and decoder you can use with an XML API.
This module adds support for encoding and decoding SOAP Body objects via JAXB and SOAPMessage. It also provides SOAPFault decoding capabilities by wrapping them into the original javax.xml.ws.soap.SOAPFaultException
, so that you'll only need to catch SOAPFaultException
in order to handle SOAPFault.
Add SOAPEncoder
and/or SOAPDecoder
to your Feign.Builder
like so:
public class Example {
public static void main(String[] args) {
Api api = Feign.builder()
.encoder(new SOAPEncoder(jaxbFactory))
.decoder(new SOAPDecoder(jaxbFactory))
.errorDecoder(new SOAPErrorDecoder())
.target(MyApi.class, "http://api");
}
}
NB: you may also need to add SOAPErrorDecoder
if SOAP Faults are returned in response with error http codes (4xx, 5xx, ...)
SLF4JModule allows directing Feign's logging to SLF4J, allowing you to easily use a logging backend of your choice (Logback, Log4J, etc.)
To use SLF4J with Feign, add both the SLF4J module and an SLF4J binding of your choice to your classpath. Then, configure Feign to use the Slf4jLogger:
public class Example {
public static void main(String[] args) {
GitHub github = Feign.builder()
.logger(new Slf4jLogger())
.logLevel(Level.FULL)
.target(GitHub.class, "https://api.github.com");
}
}
Feign.builder()
allows you to specify additional configuration such as how to decode a response.
If any methods in your interface return types besides Response
, String
, byte[]
or void
, you'll need to configure a non-default Decoder
.
Here's how to configure JSON decoding (using the feign-gson
extension):
public class Example {
public static void main(String[] args) {
GitHub github = Feign.builder()
.decoder(new GsonDecoder())
.target(GitHub.class, "https://api.github.com");
}
}
If you need to pre-process the response before give it to the Decoder, you can use the mapAndDecode
builder method.
An example use case is dealing with an API that only serves jsonp, you will maybe need to unwrap the jsonp before
send it to the Json decoder of your choice:
public class Example {
public static void main(String[] args) {
JsonpApi jsonpApi = Feign.builder()
.mapAndDecode((response, type) -> jsopUnwrap(response, type), new GsonDecoder())
.target(JsonpApi.class, "https://some-jsonp-api.com");
}
}
If any methods in your interface return type Stream
, you'll need to configure a StreamDecoder
.
Here's how to configure Stream decoder without delegate decoder:
public class Example {
public static void main(String[] args) {
GitHub github = Feign.builder()
.decoder(StreamDecoder.create((r, t) -> {
BufferedReader bufferedReader = new BufferedReader(r.body().asReader(UTF_8));
return bufferedReader.lines().iterator();
}))
.target(GitHub.class, "https://api.github.com");
}
}
Here's how to configure Stream decoder with delegate decoder:
public class Example {
public static void main(String[] args) {
GitHub github = Feign.builder()
.decoder(StreamDecoder.create((r, t) -> {
BufferedReader bufferedReader = new BufferedReader(r.body().asReader(UTF_8));
return bufferedReader.lines().iterator();
}, (r, t) -> "this is delegate decoder"))
.target(GitHub.class, "https://api.github.com");
}
}
The simplest way to send a request body to a server is to define a POST
method that has a String
or byte[]
parameter without any annotations on it. You will likely need to add a Content-Type
header.
interface LoginClient {
@RequestLine("POST /")
@Headers("Content-Type: application/json")
void login(String content);
}
public class Example {
public static void main(String[] args) {
client.login("{\"user_name\": \"denominator\", \"password\": \"secret\"}");
}
}
By configuring an Encoder
, you can send a type-safe request body. Here's an example using the feign-gson
extension:
static class Credentials {
final String user_name;
final String password;
Credentials(String user_name, String password) {
this.user_name = user_name;
this.password = password;
}
}
interface LoginClient {
@RequestLine("POST /")
void login(Credentials creds);
}
public class Example {
public static void main(String[] args) {
LoginClient client = Feign.builder()
.encoder(new GsonEncoder())
.target(LoginClient.class, "https://foo.com");
client.login(new Credentials("denominator", "secret"));
}
}
The @Body
annotation indicates a template to expand using parameters annotated with @Param
. You will likely need to add a Content-Type
header.
interface LoginClient {
@RequestLine("POST /")
@Headers("Content-Type: application/xml")
@Body("<login \"user_name\"=\"{user_name}\" \"password\"=\"{password}\"/>")
void xml(@Param("user_name") String user, @Param("password") String password);
@RequestLine("POST /")
@Headers("Content-Type: application/json")
// json curly braces must be escaped!
@Body("%7B\"user_name\": \"{user_name}\", \"password\": \"{password}\"%7D")
void json(@Param("user_name") String user, @Param("password") String password);
}
public class Example {
public static void main(String[] args) {
client.xml("denominator", "secret"); // <login "user_name"="denominator" "password"="secret"/>
client.json("denominator", "secret"); // {"user_name": "denominator", "password": "secret"}
}
}
Feign supports settings headers on requests either as part of the api or as part of the client depending on the use case.
In cases where specific interfaces or calls should always have certain header values set, it makes sense to define headers as part of the api.
Static headers can be set on an api interface or method using the @Headers
annotation.
@Headers("Accept: application/json")
interface BaseApi<V> {
@Headers("Content-Type: application/json")
@RequestLine("PUT /api/{key}")
void put(@Param("key") String key, V value);
}
Methods can specify dynamic content for static headers using variable expansion in @Headers
.
public interface Api {
@RequestLine("POST /")
@Headers("X-Ping: {token}")
void post(@Param("token") String token);
}
In cases where both the header field keys and values are dynamic and the range of possible keys cannot
be known ahead of time and may vary between different method calls in the same api/client (e.g. custom
metadata header fields such as "x-amz-meta-*" or "x-goog-meta-*"), a Map parameter can be annotated
with HeaderMap
to construct a query that uses the contents of the map as its header parameters.
public interface Api {
@RequestLine("POST /")
void post(@HeaderMap Map<String, Object> headerMap);
}
These approaches specify header entries as part of the api and do not require any customizations when building the Feign client.
To customize headers for each request method on a Target, a RequestInterceptor can be used. RequestInterceptors can be shared across Target instances and are expected to be thread-safe. RequestInterceptors are applied to all request methods on a Target.
If you need per method customization, a custom Target is required, as the a RequestInterceptor does not have access to the current method metadata.
For an example of setting headers using a RequestInterceptor
, see the Request Interceptors
section.
Headers can be set as part of a custom Target
.
static class DynamicAuthTokenTarget<T> implements Target<T> {
public DynamicAuthTokenTarget(Class<T> clazz,
UrlAndTokenProvider provider,
ThreadLocal<String> requestIdProvider);
@Override
public Request apply(RequestTemplate input) {
TokenIdAndPublicURL urlAndToken = provider.get();
if (input.url().indexOf("http") != 0) {
input.insert(0, urlAndToken.publicURL);
}
input.header("X-Auth-Token", urlAndToken.tokenId);
input.header("X-Request-ID", requestIdProvider.get());
return input.request();
}
}
public class Example {
public static void main(String[] args) {
Bank bank = Feign.builder()
.target(new DynamicAuthTokenTarget(Bank.class, provider, requestIdProvider));
}
}
These approaches depend on the custom RequestInterceptor
or Target
being set on the Feign
client when it is built and can be used as a way to set headers on all api calls on a per-client
basis. This can be useful for doing things such as setting an authentication token in the header
of all api requests on a per-client basis. The methods are run when the api call is made on the
thread that invokes the api call, which allows the headers to be set dynamically at call time and
in a context-specific manner -- for example, thread-local storage can be used to set different
header values depending on the invoking thread, which can be useful for things such as setting
thread-specific trace identifiers for requests.
In many cases, apis for a service follow the same conventions. Feign supports this pattern via single-inheritance interfaces.
Consider the example:
interface BaseAPI {
@RequestLine("GET /health")
String health();
@RequestLine("GET /all")
List<Entity> all();
}
You can define and target a specific api, inheriting the base methods.
interface CustomAPI extends BaseAPI {
@RequestLine("GET /custom")
String custom();
}
In many cases, resource representations are also consistent. For this reason, type parameters are supported on the base api interface.
@Headers("Accept: application/json")
interface BaseApi<V> {
@RequestLine("GET /api/{key}")
V get(@Param("key") String key);
@RequestLine("GET /api")
List<V> list();
@Headers("Content-Type: application/json")
@RequestLine("PUT /api/{key}")
void put(@Param("key") String key, V value);
}
interface FooApi extends BaseApi<Foo> { }
interface BarApi extends BaseApi<Bar> { }
You can log the http messages going to and from the target by setting up a Logger
. Here's the easiest way to do that:
public class Example {
public static void main(String[] args) {
GitHub github = Feign.builder()
.decoder(new GsonDecoder())
.logger(new Logger.JavaLogger("GitHub.Logger").appendToFile("logs/http.log"))
.logLevel(Logger.Level.FULL)
.target(GitHub.class, "https://api.github.com");
}
}
A Note on JavaLogger: Avoid using of default
JavaLogger()
constructor - it was marked as deprecated and will be removed soon.
The SLF4JLogger (see above) may also be of interest.
To filter out sensitive information like authorization or tokens
override methods shouldLogRequestHeader
or shouldLogResponseHeader
.
When you need to change all requests, regardless of their target, you'll want to configure a RequestInterceptor
.
For example, if you are acting as an intermediary, you might want to propagate the X-Forwarded-For
header.
static class ForwardedForInterceptor implements RequestInterceptor {
@Override public void apply(RequestTemplate template) {
template.header("X-Forwarded-For", "origin.host.com");
}
}
public class Example {
public static void main(String[] args) {
Bank bank = Feign.builder()
.decoder(accountDecoder)
.requestInterceptor(new ForwardedForInterceptor())
.target(Bank.class, "https://api.examplebank.com");
}
}
Another common example of an interceptor would be authentication, such as using the built-in BasicAuthRequestInterceptor
.
public class Example {
public static void main(String[] args) {
Bank bank = Feign.builder()
.decoder(accountDecoder)
.requestInterceptor(new BasicAuthRequestInterceptor(username, password))
.target(Bank.class, "https://api.examplebank.com");
}
}
Parameters annotated with Param
expand based on their toString
. By
specifying a custom Param.Expander
, users can control this behavior,
for example formatting dates.
public interface Api {
@RequestLine("GET /?since={date}") Result list(@Param(value = "date", expander = DateToMillis.class) Date date);
}
A Map parameter can be annotated with QueryMap
to construct a query that uses the contents of the map as its query parameters.
public interface Api {
@RequestLine("GET /find")
V find(@QueryMap Map<String, Object> queryMap);
}
This may also be used to generate the query parameters from a POJO object using a QueryMapEncoder
.
public interface Api {
@RequestLine("GET /find")
V find(@QueryMap CustomPojo customPojo);
}
When used in this manner, without specifying a custom QueryMapEncoder
, the query map will be generated using member variable names as query parameter names. The following POJO will generate query params of "/find?name={name}&number={number}" (order of included query parameters not guaranteed, and as usual, if any value is null, it will be left out).
public class CustomPojo {
private final String name;
private final int number;
public CustomPojo (String name, int number) {
this.name = name;
this.number = number;
}
}
To setup a custom QueryMapEncoder
:
public class Example {
public static void main(String[] args) {
MyApi myApi = Feign.builder()
.queryMapEncoder(new MyCustomQueryMapEncoder())
.target(MyApi.class, "https://api.hostname.com");
}
}
When annotating objects with @QueryMap, the default encoder uses reflection to inspect provided objects Fields to expand the objects values into a query string. If you prefer that the query string be built using getter and setter methods, as defined in the Java Beans API, please use the BeanQueryMapEncoder
public class Example {
public static void main(String[] args) {
MyApi myApi = Feign.builder()
.queryMapEncoder(new BeanQueryMapEncoder())
.target(MyApi.class, "https://api.hostname.com");
}
}
If you need more control over handling unexpected responses, Feign instances can
register a custom ErrorDecoder
via the builder.
public class Example {
public static void main(String[] args) {
MyApi myApi = Feign.builder()
.errorDecoder(new MyErrorDecoder())
.target(MyApi.class, "https://api.hostname.com");
}
}
All responses that result in an HTTP status not in the 2xx range will trigger the ErrorDecoder
's decode
method, allowing
you to handle the response, wrap the failure into a custom exception or perform any additional processing.
If you want to retry the request again, throw a RetryableException
. This will invoke the registered
Retryer
.
Feign, by default, will automatically retry IOException
s, regardless of HTTP method, treating them as transient network
related exceptions, and any RetryableException
thrown from an ErrorDecoder
. To customize this
behavior, register a custom Retryer
instance via the builder.
public class Example {
public static void main(String[] args) {
MyApi myApi = Feign.builder()
.retryer(new MyRetryer())
.target(MyApi.class, "https://api.hostname.com");
}
}
Retryer
s are responsible for determining if a retry should occur by returning either a true
or
false
from the method continueOrPropagate(RetryableException e);
A Retryer
instance will be
created for each Client
execution, allowing you to maintain state bewteen each request if desired.
If the retry is determined to be unsuccessful, the last RetryException
will be thrown. To throw the original
cause that led to the unsuccessful retry, build your Feign client with the exceptionPropagationPolicy()
option.
By default, feign won't collect any metrics.
But, it's possible to add metric collection capabilities to any feign client.
Metric Capabilities provide a first-class Metrics API that users can tap into to gain insight into the request/response lifecycle.
public class MyApp {
public static void main(String[] args) {
GitHub github = Feign.builder()
.addCapability(new Metrics4Capability())
.target(GitHub.class, "https://api.github.com");
github.contributors("OpenFeign", "feign");
// metrics will be available from this point onwards
}
}
public class MyApp {
public static void main(String[] args) {
GitHub github = Feign.builder()
.addCapability(new Metrics5Capability())
.target(GitHub.class, "https://api.github.com");
github.contributors("OpenFeign", "feign");
// metrics will be available from this point onwards
}
}
public class MyApp {
public static void main(String[] args) {
GitHub github = Feign.builder()
.addCapability(new MicrometerCapability())
.target(GitHub.class, "https://api.github.com");
github.contributors("OpenFeign", "feign");
// metrics will be available from this point onwards
}
}
Interfaces targeted by Feign may have static or default methods (if using Java 8+). These allows Feign clients to contain logic that is not expressly defined by the underlying API. For example, static methods make it easy to specify common client build configurations; default methods can be used to compose queries or define default parameters.
interface GitHub {
@RequestLine("GET /repos/{owner}/{repo}/contributors")
List<Contributor> contributors(@Param("owner") String owner, @Param("repo") String repo);
@RequestLine("GET /users/{username}/repos?sort={sort}")
List<Repo> repos(@Param("username") String owner, @Param("sort") String sort);
default List<Repo> repos(String owner) {
return repos(owner, "full_name");
}
/**
* Lists all contributors for all repos owned by a user.
*/
default List<Contributor> contributors(String user) {
MergingContributorList contributors = new MergingContributorList();
for(Repo repo : this.repos(owner)) {
contributors.addAll(this.contributors(user, repo.getName()));
}
return contributors.mergeResult();
}
static GitHub connect() {
return Feign.builder()
.decoder(new GsonDecoder())
.target(GitHub.class, "https://api.github.com");
}
}
Feign 10.8 introduces a new builder AsyncFeign
that allow methods to return CompletableFuture
instances.
interface GitHub {
@RequestLine("GET /repos/{owner}/{repo}/contributors")
CompletableFuture<List<Contributor>> contributors(@Param("owner") String owner, @Param("repo") String repo);
}
public class MyApp {
public static void main(String... args) {
GitHub github = AsyncFeign.builder()
.decoder(new GsonDecoder())
.target(GitHub.class, "https://api.github.com");
// Fetch and print a list of the contributors to this library.
CompletableFuture<List<Contributor>> contributors = github.contributors("OpenFeign", "feign");
for (Contributor contributor : contributors.get(1, TimeUnit.SECONDS)) {
System.out.println(contributor.login + " (" + contributor.contributions + ")");
}
}
}
Initial implementation include 2 async clients:
AsyncClient.Default
AsyncApacheHttp5Client
Keeping all feign libraries on the same version is essential to avoid incompatible binaries. When consuming external dependencies, can be tricky to make sure only one version is present.
With that in mind, feign build generates a module called feign-bom
that locks the versions for all feign-*
modules.
The Bill Of Material is a special POM file that groups dependency versions that are known to be valid and tested to work together. This will reduce the developers’ pain of having to test the compatibility of different versions and reduce the chances to have version mismatches.
Here is one example of what feign BOM file looks like.
<project>
...
<dependencyManagement>
<dependencies>
<dependency>
<groupId>io.github.openfeign</groupId>
<artifactId>feign-bom</artifactId>
<version>??feign.version??</version>
<type>pom</type>
<scope>import</scope>
</dependency>
</dependencies>
</dependencyManagement>
</project>