Authorization of web endpoints
Quarkus incorporates a pluggable web security layer. When security is active, the system performs a permission check on all HTTP requests to determine if they should proceed.
Using @PermitAll will not open a path if the path is restricted by the quarkus.http.auth. configuration.
To ensure specific paths are accessible, appropriate configurations must be made within the Quarkus security settings.
|
If you use Jakarta RESTful Web Services, consider using |
Authorization is based on user roles that the security provider provides.
To customize these roles, a SecurityIdentityAugmentor can be created, see
Security Identity Customization.
Authorization using configuration
Permissions are defined in the Quarkus configuration by permission sets, each specifying a policy for access control.
| Built-in policy | Descrição |
|---|---|
|
This policy denies all users. |
|
This policy permits all users. |
|
This policy permits only authenticated users. |
You can define role-based policies that allow users with specific roles to access the resources.
quarkus.http.auth.policy.role-policy1.roles-allowed=user,admin (1)| 1 | This defines a role-based policy that allows users with the user and admin roles. |
You can reference a custom policy by configuring the built-in permission sets that are defined in the application.properties file, as outlined in the following configuration example:
quarkus.http.auth.permission.permit1.paths=/public/* (1)
quarkus.http.auth.permission.permit1.policy=permit
quarkus.http.auth.permission.permit1.methods=GET
quarkus.http.auth.permission.deny1.paths=/forbidden (2)
quarkus.http.auth.permission.deny1.policy=deny
quarkus.http.auth.permission.roles1.paths=/roles-secured/*,/other/*,/api/* (3)
quarkus.http.auth.permission.roles1.policy=role-policy1| 1 | This permission references the default built-in permit policy to allow GET methods to /public.
In this case, the demonstrated setting would not affect this example because this request is allowed anyway. |
| 2 | This permission references the built-in deny policy for both /forbidden and /forbidden/ paths.
It is an exact path match because it does not end with *. |
| 3 | This permission set references the previously defined policy.
roles1 is an example name; you can call the permission sets whatever you want. |
|
The exact path pattern
If you need to permit access to the
|
Custom HttpSecurityPolicy
Sometimes it might be useful to register your own named policy. You can get it done by creating application scoped CDI
bean that implements the io.quarkus.vertx.http.runtime.security.HttpSecurityPolicy interface like in the example below:
import jakarta.enterprise.context.ApplicationScoped;
import io.quarkus.security.identity.SecurityIdentity;
import io.quarkus.vertx.http.runtime.security.HttpSecurityPolicy;
import io.smallrye.mutiny.Uni;
import io.vertx.ext.web.RoutingContext;
@ApplicationScoped
public class CustomNamedHttpSecPolicy implements HttpSecurityPolicy {
@Override
public Uni<CheckResult> checkPermission(RoutingContext event, Uni<SecurityIdentity> identity,
AuthorizationRequestContext requestContext) {
if (customRequestAuthorization(event)) {
return Uni.createFrom().item(CheckResult.PERMIT);
}
return Uni.createFrom().item(CheckResult.DENY);
}
@Override
public String name() {
return "custom"; (1)
}
private static boolean customRequestAuthorization(RoutingContext event) {
// here comes your own security check
return !event.request().path().endsWith("denied");
}
}| 1 | Named HTTP Security policy will only be applied to requests matched by the application.properties path matching rules. |
quarkus.http.auth.permission.custom1.paths=/custom/*
quarkus.http.auth.permission.custom1.policy=custom (1)| 1 | Custom policy name must match the value returned by the io.quarkus.vertx.http.runtime.security.HttpSecurityPolicy.name method. |
Alternatively, you can bind custom named HttpSecurityPolicy to Jakarta REST endpoints with the @AuthorizationPolicy security annotation.
| 1 | The @AuthorizationPolicy annotation can be used together with other standard security annotations.
As usual, the method-level annotation has priority over class-level annotation. |
| 2 | Apply custom named HttpSecurityPolicy to the Jakarta REST hello endpoint. |
|
You can also create global |
Matching on paths and methods
Permission sets can also specify paths and methods as a comma-separated list.
If a path ends with the * wildcard, the query it generates matches all sub-paths.
Otherwise, it queries for an exact match and only matches that specific path:
quarkus.http.auth.permission.permit1.paths=/public*,/css/*,/js/*,/robots.txt (1)
quarkus.http.auth.permission.permit1.policy=permit
quarkus.http.auth.permission.permit1.methods=GET,HEAD| 1 | The * wildcard at the end of the path matches zero or more path segments, but never any word starting from the /public path.
For that reason, a path like /public-info is not matched by this pattern. |
Matching a path but not a method
The request is rejected if it matches one or more permission sets based on the path but none of the required methods.
|
Given the preceding permission set, |
Matching multiple paths: longest path wins
Matching is always done on the "longest path wins" basis. Less specific permission sets are not considered if a more specific one has been matched:
quarkus.http.auth.permission.permit1.paths=/public/*
quarkus.http.auth.permission.permit1.policy=permit
quarkus.http.auth.permission.permit1.methods=GET,HEAD
quarkus.http.auth.permission.deny1.paths=/public/forbidden-folder/*
quarkus.http.auth.permission.deny1.policy=deny|
Given the preceding permission set, |
|
Subpath permissions precede root path permissions, as the This rule is further exemplified by a scenario where subpath permission allows access to a public resource while the root path permission necessitates authorization. |
Matching multiple sub-paths: longest path to the * wildcard wins
Previous examples demonstrated matching all sub-paths when a path concludes with the *
wildcard.
This wildcard also applies in the middle of a path, representing a single path segment.
It cannot be mixed with other path segment characters; thus, path separators always enclose the * wildcard, as seen in the /public/*/about-us path.
When several path patterns correspond to the same request path, the system selects the longest sub-path leading to the * wildcard.
In this context, every path segment character is more specific than the *
wildcard.
Here is a simple example:
quarkus.http.auth.permission.secured.paths=/api/*/detail (1)
quarkus.http.auth.permission.secured.policy=authenticated
quarkus.http.auth.permission.public.paths=/api/public-product/detail (2)
quarkus.http.auth.permission.public.policy=permit| 1 | Request paths like /api/product/detail can only be accessed by authenticated users. |
| 2 | The path /api/public-product/detail is more specific, therefore accessible by anyone. |
|
All paths secured with the authorization using configuration should be tested. Writing path patterns with multiple wildcards can be cumbersome. Please make sure paths are authorized as you intended. |
In the following example, paths are ordered from the most specific to the least specific one:
/one/two/three/four/five matches ordered from the most specific to the least specific path/one/two/three/four/five
/one/two/three/four/*
/one/two/three/*/five
/one/two/three/*/*
/one/two/*/four/five
/one/*/three/four/five
/*/two/three/four/five
/*/two/three/*/five
/*|
The |
Matching multiple paths: most specific method wins
When a path is registered with multiple permission sets, the permission sets explicitly specifying an HTTP method that matches the request take precedence. In this instance, the permission sets without methods only come into effect if the request method does not match permission sets with the method specification.
quarkus.http.auth.permission.permit1.paths=/public/*
quarkus.http.auth.permission.permit1.policy=permit
quarkus.http.auth.permission.permit1.methods=GET,HEAD
quarkus.http.auth.permission.deny1.paths=/public/*
quarkus.http.auth.permission.deny1.policy=deny|
The preceding permission set shows that In contrast, |
Matching multiple paths and methods: both win
Sometimes, the previously described rules allow multiple permission sets to win simultaneously. In that case, for the request to proceed, all the permissions must allow access. For this to happen, both must either have specified the method or have no method. Method-specific matches take precedence.
quarkus.http.auth.policy.user-policy1.roles-allowed=user
quarkus.http.auth.policy.admin-policy1.roles-allowed=admin
quarkus.http.auth.permission.roles1.paths=/api/*,/restricted/*
quarkus.http.auth.permission.roles1.policy=user-policy1
quarkus.http.auth.permission.roles2.paths=/api/*,/admin/*
quarkus.http.auth.permission.roles2.policy=admin-policy1
Given the preceding permission set, GET /api/foo would match both permission sets' paths, requiring both the user and admin roles.
|
Configuration properties to deny access
The following configuration settings alter the role-based access control (RBAC) denying behavior:
quarkus.security.jaxrs.deny-unannotated-endpoints=true|false-
If set to true, access is denied for all Jakarta REST endpoints by default. If a Jakarta REST endpoint has no security annotations, it defaults to the
@DenyAllbehavior. This helps you to avoid accidentally exposing an endpoint that is supposed to be secured. Defaults tofalse. quarkus.security.jaxrs.default-roles-allowed=role1,role2-
Defines the default role requirements for unannotated endpoints. The
**role is a special role that means any authenticated user. This cannot be combined withdeny-unannotated-endpointsbecausedenytakes effect instead. quarkus.security.deny-unannotated-members=true|false-
If set to true, the access is denied to all CDI methods and Jakarta REST endpoints that do not have security annotations but are defined in classes that contain methods with security annotations. Defaults to
false.
Disabling permissions
Permissions can be disabled at build time with an enabled property for each declared permission, such as:
quarkus.http.auth.permission.permit1.enabled=false
quarkus.http.auth.permission.permit1.paths=/public/*,/css/*,/js/*,/robots.txt
quarkus.http.auth.permission.permit1.policy=permit
quarkus.http.auth.permission.permit1.methods=GET,HEADPermissions can be reenabled at runtime with a system property or environment variable, such as:
-Dquarkus.http.auth.permission.permit1.enabled=true.
Permission paths and HTTP root path
The quarkus.http.root-path configuration property changes the http endpoint context path.
By default, quarkus.http.root-path is prepended automatically to configured permission paths then do not use a forward slash, for example:
quarkus.http.auth.permission.permit1.paths=public/*,css/*,js/*,robots.txtThis configuration is equivalent to the following:
quarkus.http.auth.permission.permit1.paths=${quarkus.http.root-path}/public/*,${quarkus.http.root-path}/css/*,${quarkus.http.root-path}/js/*,${quarkus.http.root-path}/robots.txtA leading slash changes how the configured permission path is interpreted.
The configured URL is used as-is, and paths are not adjusted if the value of quarkus.http.root-path changes.
quarkus.http.auth.permission.permit1.paths=/public/*,css/*,js/*,robots.txtThis configuration only impacts resources served from the fixed or static URL, /public, which might not match your application resources if quarkus.http.root-path has been set to something other than /.
For more information, see Path Resolution in Quarkus.
Map SecurityIdentity roles
Winning role-based policy can map the SecurityIdentity roles to the deployment-specific roles.
These roles are then applicable for endpoint authorization by using the @RolesAllowed annotation.
quarkus.http.auth.policy.admin-policy1.roles.admin=Admin1 (1)
quarkus.http.auth.permission.roles1.paths=/* (2)
quarkus.http.auth.permission.roles1.policy=admin-policy1| 1 | Map the admin role to Admin1 role. The SecurityIdentity will have both admin and Admin1 roles. |
| 2 | The /* path is secured, only authenticated HTTP requests are granted access. |
If all that you need is to map the SecurityIdentity roles to the deployment-specific roles regardless of a path, you can also do this:
quarkus.http.auth.roles-mapping.admin=Admin1 (1) (2)| 1 | Map the admin role to Admin1 role. The SecurityIdentity will have both admin and Admin1 roles. |
| 2 | The /* path is not secured. You must secure your endpoints with standard security annotations or define HTTP permissions in addition to this configuration property. |
Shared permission checks
One important rule for unshared permission checks is that only one path match is applied, the most specific one. Naturally you can specify as many permissions with the same winning path as you want and they will all be applied. However, there can be permission checks you want to apply to many paths without repeating them over and over again. That’s where shared permission checks come in, they are always applied when the permission path is matched.
quarkus.http.auth.permission.custom1.paths=/*
quarkus.http.auth.permission.custom1.shared=true (1)
quarkus.http.auth.permission.custom1.policy=custom
quarkus.http.auth.policy.admin-policy1.roles-allowed=admin
quarkus.http.auth.permission.roles1.paths=/admin/*
quarkus.http.auth.permission.roles1.policy=admin-policy1| 1 | Custom HttpSecurityPolicy will be also applied on the /admin/1 path together with the admin-policy1 policy. |
| Configuring many shared permission checks is less effective than configuring unshared ones. Use shared permissions to complement unshared permission checks like in the example below. |
SecurityIdentity roles with shared permissionquarkus.http.auth.policy.role-policy1.roles.root=admin,user (1)
quarkus.http.auth.permission.roles1.paths=/secured/* (2)
quarkus.http.auth.permission.roles1.policy=role-policy1
quarkus.http.auth.permission.roles1.shared=true
quarkus.http.auth.policy.role-policy2.roles-allowed=user (3)
quarkus.http.auth.permission.roles2.paths=/secured/user/*
quarkus.http.auth.permission.roles2.policy=role-policy2
quarkus.http.auth.policy.role-policy3.roles-allowed=admin
quarkus.http.auth.permission.roles3.paths=/secured/admin/*
quarkus.http.auth.permission.roles3.policy=role-policy3| 1 | Role root will be able to access /secured/user/* and /secured/admin/* paths. |
| 2 | The /secured/* path can only be accessed by authenticated users. This way, you have secured the /secured/all path and so on. |
| 3 | Shared permissions are always applied before unshared ones, therefore a SecurityIdentity with the root role will have the user role as well. |
Authorization using annotations
Quarkus includes built-in security to allow for Role-Based Access Control (RBAC)
based on the common security annotations @RolesAllowed, @DenyAll, @PermitAll on REST endpoints and CDI beans.
| Annotation type | Descrição |
|---|---|
|
Specifies that no security roles are allowed to invoke the specified methods. |
|
Specifies that all security roles are allowed to invoke the specified methods.
|
|
Specifies the list of security roles allowed to access methods in an application. |
|
Quarkus provides the |
|
Specifies the list of permissions that are allowed to invoke the specified methods. |
|
Specifies named |
The following SubjectExposingResource example demonstrates an endpoint that uses both Jakarta REST and Common Security annotations to describe and secure its endpoints.
import java.security.Principal;
import jakarta.annotation.security.DenyAll;
import jakarta.annotation.security.PermitAll;
import jakarta.annotation.security.RolesAllowed;
import jakarta.ws.rs.GET;
import jakarta.ws.rs.Path;
import jakarta.ws.rs.core.Context;
import jakarta.ws.rs.core.SecurityContext;
@Path("subject")
public class SubjectExposingResource {
@GET
@Path("secured")
@RolesAllowed("Tester") (1)
public String getSubjectSecured(@Context SecurityContext sec) {
Principal user = sec.getUserPrincipal(); (2)
String name = user != null ? user.getName() : "anonymous";
return name;
}
@GET
@Path("authenticated")
@Authenticated (3)
public String getSubjectAuthenticated(@Context SecurityContext sec) {
Principal user = sec.getUserPrincipal();
String name = user != null ? user.getName() : "anonymous";
return name;
}
@GET
@Path("unsecured")
@PermitAll (4)
public String getSubjectUnsecured(@Context SecurityContext sec) {
Principal user = sec.getUserPrincipal(); (5)
String name = user != null ? user.getName() : "anonymous";
return name;
}
@GET
@Path("denied")
@DenyAll (6)
public String getSubjectDenied(@Context SecurityContext sec) {
Principal user = sec.getUserPrincipal();
String name = user != null ? user.getName() : "anonymous";
return name;
}
}| 1 | The /subject/secured endpoint requires an authenticated user with the granted "Tester" role through the use of the @RolesAllowed("Tester") annotation. |
| 2 | The endpoint obtains the user principal from the Jakarta REST SecurityContext.
This returns non-null for a secured endpoint. |
| 3 | The /subject/authenticated endpoint allows any authenticated user by specifying the @Authenticated annotation. |
| 4 | The /subject/unsecured endpoint allows for unauthenticated access by specifying the @PermitAll annotation. |
| 5 | The call to obtain the user principal returns null if the caller is unauthenticated and non-null if the caller is authenticated. |
| 6 | The /subject/denied endpoint declares the @DenyAll annotation, disallowing all direct access to it as a REST method, regardless of the user calling it.
The method is still invokable internally by other methods in this class. |
| If you plan to use standard security annotations on the IO thread, review the information in Proactive Authentication. |
The @RolesAllowed annotation value supports property expressions including default values and nested property expressions.
Configuration properties used with the annotation are resolved at runtime.
| Annotation | Value explanation |
|---|---|
|
The endpoint allows users with the role denoted by the value of the |
|
An example showing that the value can contain multiple variables. |
|
A default value demonstration.
The required role is denoted by the value of the |
@RolesAllowed annotationadmin=Administrator
tester.group=Software
tester.role=Tester
%prod.secured=User
%dev.secured=**
all-roles=Administrator,Software,Tester,Userimport java.security.Principal;
import jakarta.annotation.security.RolesAllowed;
import jakarta.ws.rs.GET;
import jakarta.ws.rs.Path;
import jakarta.ws.rs.core.Context;
import jakarta.ws.rs.core.SecurityContext;
@Path("subject")
public class SubjectExposingResource {
@GET
@Path("admin")
@RolesAllowed("${admin}") (1)
public String getSubjectSecuredAdmin(@Context SecurityContext sec) {
return getUsername(sec);
}
@GET
@Path("software-tester")
@RolesAllowed("${tester.group}-${tester.role}") (2)
public String getSubjectSoftwareTester(@Context SecurityContext sec) {
return getUsername(sec);
}
@GET
@Path("user")
@RolesAllowed("${customer:User}") (3)
public String getSubjectUser(@Context SecurityContext sec) {
return getUsername(sec);
}
@GET
@Path("secured")
@RolesAllowed("${secured}") (4)
public String getSubjectSecured(@Context SecurityContext sec) {
return getUsername(sec);
}
@GET
@Path("list")
@RolesAllowed("${all-roles}") (5)
public String getSubjectList(@Context SecurityContext sec) {
return getUsername(sec);
}
private String getUsername(SecurityContext sec) {
Principal user = sec.getUserPrincipal();
String name = user != null ? user.getName() : "anonymous";
return name;
}
}| 1 | The @RolesAllowed annotation value is set to the value of Administrator. |
| 2 | This /subject/software-tester endpoint requires an authenticated user that has been granted the role of "Software-Tester".
It is possible to use multiple expressions in the role definition. |
| 3 | This /subject/user endpoint requires an authenticated user that has been granted the role "User" through the use of the @RolesAllowed("${customer:User}") annotation because we did not set the configuration property customer. |
| 4 | In production, this /subject/secured endpoint requires an authenticated user with the User role.
In development mode, it allows any authenticated user. |
| 5 | Property expression all-roles will be treated as a collection type List, therefore, the endpoint will be accessible for roles Administrator, Software, Tester and User. |
Endpoint security annotations and Jakarta REST inheritance
Quarkus supports security annotations placed on the endpoint implementation or its class like in the example below:
@Path("hello")
public interface HelloInterface {
@GET
String hello();
}
@DenyAll (1)
public class HelloInterfaceImpl implements HelloInterface {
@RolesAllowed("admin") (2)
@Override
public String hello() {
return "Hello";
}
}| 1 | Class-level security annotation must be placed on the class where the endpoint implementation is declared. |
| 2 | Method-level security annotation must be placed on the endpoint implementation. |
|
The RESTEasy subresource locators declared as default interface methods cannot be secured by standard security annotations. Secured subresource locators must be implemented and secured on the interface implementors like in the example below: |
Permission annotation
Quarkus also provides the io.quarkus.security.PermissionsAllowed annotation, which authorizes any authenticated user with the given permission to access the resource.
This annotation is an extension of the common security annotations and checks the permissions granted to a SecurityIdentity instance.
@PermissionsAllowed annotationpackage org.acme.crud;
import io.quarkus.arc.Arc;
import io.vertx.ext.web.RoutingContext;
import jakarta.ws.rs.GET;
import jakarta.ws.rs.POST;
import jakarta.ws.rs.Path;
import jakarta.ws.rs.QueryParam;
import io.quarkus.security.PermissionsAllowed;
import java.security.BasicPermission;
import java.security.Permission;
import java.util.Collection;
import java.util.Collections;
@Path("/crud")
public class CRUDResource {
@PermissionsAllowed("create") (1)
@PermissionsAllowed("update")
@POST
@Path("/modify/repeated")
public String createOrUpdate() {
return "modified";
}
@PermissionsAllowed(value = {"create", "update"}, inclusive=true) (2)
@POST
@Path("/modify/inclusive")
public String createOrUpdate(Long id) {
return id + " modified";
}
@PermissionsAllowed({"see:detail", "see:all", "read"}) (3)
@GET
@Path("/id/{id}")
public String getItem(String id) {
return "item-detail-" + id;
}
@PermissionsAllowed(value = "list", permission = CustomPermission.class) (4)
@Path("/list")
@GET
public Collection<String> list(@QueryParam("query-options") String queryOptions) {
// your business logic comes here
return Collections.emptySet();
}
public static class CustomPermission extends BasicPermission {
public CustomPermission(String name) {
super(name);
}
@Override
public boolean implies(Permission permission) {
var event = Arc.container().instance(RoutingContext.class).get(); (5)
var publicContent = "public-content".equals(event.request().params().get("query-options"));
var hasPermission = getName().equals(permission.getName());
return hasPermission && publicContent;
}
}
}| 1 | The resource method createOrUpdate is only accessible for a user with both create and update permissions. |
| 2 | By default, at least one of the permissions specified through one annotation instance is required.
You can require all permissions by setting inclusive=true.
Both resource methods createOrUpdate have equal authorization requirements. |
| 3 | Access is granted to getItem if SecurityIdentity has either read permission or see permission and one of the all or detail actions. |
| 4 | You can use your preferred java.security.Permission implementation.
By default, string-based permission is performed by io.quarkus.security.StringPermission. |
| 5 | Permissions are not beans, therefore the only way to obtain bean instances is programmatically by using Arc.container(). |
If you plan to use the @PermissionsAllowed on the IO thread, review the information in Proactive Authentication.
|
@PermissionsAllowed is not repeatable on the class level due to a limitation with Quarkus interceptors.
For more information, see the Repeatable interceptor bindings section of the Quarkus "CDI reference" guide.
|
The easiest way to add permissions to a role-enabled SecurityIdentity instance is to map roles to permissions.
Use Authorization using configuration to grant the required SecurityIdentity permissions for CRUDResource endpoints to authenticated requests, as outlined in the following example:
quarkus.http.auth.policy.role-policy1.permissions.user=see:all (1)
quarkus.http.auth.policy.role-policy1.permissions.admin=create,update,read (2)
quarkus.http.auth.permission.roles1.paths=/crud/modify/*,/crud/id/* (3)
quarkus.http.auth.permission.roles1.policy=role-policy1
quarkus.http.auth.policy.role-policy2.permissions.user=list
quarkus.http.auth.policy.role-policy2.permission-class=org.acme.crud.CRUDResource$CustomPermission (4)
quarkus.http.auth.permission.roles2.paths=/crud/list
quarkus.http.auth.permission.roles2.policy=role-policy2| 1 | Add the permission see and the action all to the SecurityIdentity instance of the user role.
Similarly, for the @PermissionsAllowed annotation, io.quarkus.security.StringPermission is used by default. |
| 2 | Permissions create, update, and read are mapped to the role admin. |
| 3 | The role policy role-policy1 allows only authenticated requests to access /crud/modify and /crud/id sub-paths.
For more information about the path-matching algorithm, see Matching multiple paths: longest path wins later in this guide. |
| 4 | You can specify a custom implementation of the java.security.Permission class.
Your custom class must define exactly one constructor that accepts the permission name and optionally some actions, for example, String array.
In this scenario, the permission list is added to the SecurityIdentity instance as new CustomPermission("list"). |
You can also create a custom java.security.Permission class with additional constructor parameters.
These additional parameters names get matched with arguments names of the method annotated with the @PermissionsAllowed annotation.
Later, Quarkus instantiates your custom permission with actual arguments, with which the method annotated with the @PermissionsAllowed has been invoked.
java.security.Permission class that accepts additional argumentspackage org.acme.library;
import java.security.Permission;
import java.util.Arrays;
import java.util.Set;
public class LibraryPermission extends Permission {
private final Set<String> actions;
private final Library library;
public LibraryPermission(String libraryName, String[] actions, Library library) { (1)
super(libraryName);
this.actions = Set.copyOf(Arrays.asList(actions));
this.library = library;
}
@Override
public boolean implies(Permission requiredPermission) {
if (requiredPermission instanceof LibraryPermission) {
LibraryPermission that = (LibraryPermission) requiredPermission;
boolean librariesMatch = getName().equals(that.getName());
boolean requiredLibraryIsSublibrary = library.isParentLibraryOf(that.library);
boolean hasOneOfRequiredActions = that.actions.stream().anyMatch(actions::contains);
return (librariesMatch || requiredLibraryIsSublibrary) && hasOneOfRequiredActions;
}
return false;
}
// here comes your own implementation of the `java.security.Permission` class methods
public static abstract class Library {
protected String description;
abstract boolean isParentLibraryOf(Library library);
}
public static class MediaLibrary extends Library {
@Override
boolean isParentLibraryOf(Library library) {
return library instanceof MediaLibrary;
}
}
public static class TvLibrary extends MediaLibrary {
// TvLibrary specific implementation of the 'isParentLibraryOf' method
}
}| 1 | There must be exactly one constructor of a custom Permission class.
The first parameter is always considered to be a permission name and must be of type String.
Quarkus can optionally pass permission actions to the constructor.
For this to happen, declare the second parameter as String[]. |
The LibraryPermission class permits access to the current or parent library if SecurityIdentity is allowed to perform one of the required actions, for example, read, write, or list.
The following example shows how the LibraryPermission class can be used:
package org.acme.library;
import io.quarkus.security.PermissionsAllowed;
import jakarta.enterprise.context.ApplicationScoped;
import org.acme.library.LibraryPermission.Library;
@ApplicationScoped
public class LibraryService {
@PermissionsAllowed(value = "tv:write", permission = LibraryPermission.class) (1)
public Library updateLibrary(String newDesc, Library library) {
library.description = newDesc;
return library;
}
@PermissionsAllowed(value = "tv:write", permission = LibraryPermission.class) (2)
@PermissionsAllowed(value = {"tv:read", "tv:list"}, permission = LibraryPermission.class)
public Library migrateLibrary(Library migrate, Library library) {
// migrate libraries
return library;
}
}| 1 | The formal parameter library is identified as the parameter matching same-named LibraryPermission constructor parameter.
Therefore, Quarkus will pass the library parameter to the LibraryPermission class constructor.
However, the LibraryPermission must be instantiated each time the updateLibrary method is invoked. |
| 2 | Here, the second Library parameter matches the name library,
while the migrate parameter is ignored during the LibraryPermission permission instantiation. |
LibraryPermissionpackage org.acme.library;
import io.quarkus.security.PermissionsAllowed;
import jakarta.inject.Inject;
import jakarta.ws.rs.PUT;
import jakarta.ws.rs.Path;
import jakarta.ws.rs.PathParam;
import org.acme.library.LibraryPermission.Library;
@Path("/library")
public class LibraryResource {
@Inject
LibraryService libraryService;
@PermissionsAllowed(value = "tv:write", permission = LibraryPermission.class)
@PUT
@Path("/id/{id}")
public Library updateLibrary(@PathParam("id") Integer id, Library library) {
...
}
@PUT
@Path("/service-way/id/{id}")
public Library updateLibrarySvc(@PathParam("id") Integer id, Library library) {
String newDescription = "new description " + id;
return libraryService.updateLibrary(newDescription, library);
}
}Similarly to the CRUDResource example, the following example shows how you can grant a user with the admin role permissions to update MediaLibrary:
package org.acme.library;
import io.quarkus.runtime.annotations.RegisterForReflection;
@RegisterForReflection (1)
public class MediaLibraryPermission extends LibraryPermission {
public MediaLibraryPermission(String libraryName, String[] actions) {
super(libraryName, actions, new MediaLibrary()); (2)
}
}| 1 | When building a native executable, the permission class must be registered for reflection unless it is also used in at least one io.quarkus.security.PermissionsAllowed#name parameter. More details about the @RegisterForReflection annotation can be found on the native application tips page. |
| 2 | We want to pass the MediaLibrary instance to the LibraryPermission constructor. |
quarkus.http.auth.policy.role-policy3.permissions.admin=media-library:list,media-library:read,media-library:write (1)
quarkus.http.auth.policy.role-policy3.permission-class=org.acme.library.MediaLibraryPermission
quarkus.http.auth.permission.roles3.paths=/library/*
quarkus.http.auth.permission.roles3.policy=role-policy3| 1 | Grants the permission media-library, which permits read, write, and list actions.
Because MediaLibrary is the TvLibrary class parent, a user with the admin role is also permitted to modify TvLibrary. |
The /library/* path can be tested from a Keycloak provider Dev UI page, because the user alice which is created
automatically by the Dev Services for Keycloak has an admin role.
|
The examples provided so far demonstrate role-to-permission mapping.
It is also possible to programmatically add permissions to the SecurityIdentity instance.
In the following example, SecurityIdentity is customized to add the same permission that was previously granted with the HTTP role-based policy.
LibraryPermission programmatically to SecurityIdentityimport java.security.Permission;
import java.util.function.Function;
import jakarta.enterprise.context.ApplicationScoped;
import io.quarkus.security.identity.AuthenticationRequestContext;
import io.quarkus.security.identity.SecurityIdentity;
import io.quarkus.security.identity.SecurityIdentityAugmentor;
import io.quarkus.security.runtime.QuarkusSecurityIdentity;
import io.smallrye.mutiny.Uni;
@ApplicationScoped
public class PermissionsIdentityAugmentor implements SecurityIdentityAugmentor {
@Override
public Uni<SecurityIdentity> augment(SecurityIdentity identity, AuthenticationRequestContext context) {
if (isNotAdmin(identity)) {
return Uni.createFrom().item(identity);
}
return Uni.createFrom().item(build(identity));
}
private boolean isNotAdmin(SecurityIdentity identity) {
return identity.isAnonymous() || !"admin".equals(identity.getPrincipal().getName());
}
SecurityIdentity build(SecurityIdentity identity) {
Permission possessedPermission = new MediaLibraryPermission("media-library",
new String[] { "read", "write", "list"}); (1)
return QuarkusSecurityIdentity.builder(identity)
.addPermissionChecker(new Function<Permission, Uni<Boolean>>() { (2)
@Override
public Uni<Boolean> apply(Permission requiredPermission) {
boolean accessGranted = possessedPermission.implies(requiredPermission);
return Uni.createFrom().item(accessGranted);
}
})
.build();
}
}| 1 | The permission media-library that was created can perform read, write, and list actions.
Because MediaLibrary is the TvLibrary class parent, a user with the admin role is also permitted to modify TvLibrary. |
| 2 | You can add a permission checker through io.quarkus.security.runtime.QuarkusSecurityIdentity.Builder#addPermissionChecker. |
Annotation-based permissions do not work with custom Jakarta REST SecurityContexts because there are no permissions in jakarta.ws.rs.core.SecurityContext.
|
Create permission meta-annotations
@PermissionsAllowed can also be used in meta-annotations.
For example, a new @CanWrite security annotation can be created like this:
import java.lang.annotation.ElementType;
import java.lang.annotation.Retention;
import java.lang.annotation.RetentionPolicy;
import java.lang.annotation.Target;
import io.quarkus.security.PermissionsAllowed;
@Retention(RetentionPolicy.RUNTIME)
@Target({ ElementType.METHOD, ElementType.TYPE })
@PermissionsAllowed(value = "write", permission = CustomPermission.class) (1)
public @interface CanWrite {
}| 1 | Any method or class annotated with the @CanWrite annotation is secured with this @PermissionsAllowed annotation instance. |
Pass @BeanParam parameters into a custom permission
Quarkus can map fields of a secured method parameters to a custom permission constructor parameters.
You can use this feature to pass jakarta.ws.rs.BeanParam parameters into your custom permission.
Let’s consider following Jakarta REST resource:
package org.acme.security.rest.resource;
import io.quarkus.security.PermissionsAllowed;
import jakarta.ws.rs.BeanParam;
import jakarta.ws.rs.GET;
import jakarta.ws.rs.Path;
@Path("/hello")
public class SimpleResource {
@PermissionsAllowed(value = "say:hello", permission = BeanParamPermission.class,
params = "beanParam.securityContext.userPrincipal.name") (1)
@GET
public String sayHello(@BeanParam SimpleBeanParam beanParam) {
return "Hello from " + beanParam.uriInfo.getPath();
}
}| 1 | The params annotation attribute specifies that user principal name should be passed to the BeanParamPermission constructor.
Other BeanParamPermission constructor parameters like customAuthorizationHeader and query are matched automatically.
Quarkus identifies the BeanParamPermission constructor parameters among beanParam fields and their public accessors.
To avoid ambiguous resolution, automatic detection only works for the beanParam fields.
For that reason, we had to specify path to the user principal name explicitly. |
Where the SimpleBeanParam class is declared like in the example below:
package org.acme.security.rest.dto;
import java.util.List;
import jakarta.ws.rs.HeaderParam;
import jakarta.ws.rs.QueryParam;
import jakarta.ws.rs.core.Context;
import jakarta.ws.rs.core.SecurityContext;
import jakarta.ws.rs.core.UriInfo;
public class SimpleBeanParam {
@HeaderParam("CustomAuthorization")
private String customAuthorizationHeader;
@Context
SecurityContext securityContext;
@Context
public UriInfo uriInfo;
@QueryParam("query")
public String query; (1)
public SecurityContext getSecurityContext() { (2)
return securityContext;
}
public String customAuthorizationHeader() { (3)
return customAuthorizationHeader;
}
}| 1 | Quarkus Security can only pass public fields to a custom permission constructor. |
| 2 | Quarkus Security automatically uses public getter methods if they are available. |
| 3 | The customAuthorizationHeader field is not public, therefore Quarkus access this field with the customAuthorizationHeader accessor.
That is particularly useful with Java records, where generated accessors are not prefixed with get. |
Here is an example of the BeanParamPermission permission that checks user principal, custom header and query parameter:
package org.acme.security.permission;
import java.security.Permission;
public class BeanParamPermission extends Permission {
private final String actions;
public BeanParamPermission(String permissionName, String customAuthorizationHeader, String name, String query) {
super(permissionName);
this.actions = computeActions(customAuthorizationHeader, name, query);
}
@Override
public boolean implies(Permission p) {
boolean nameMatches = getName().equals(p.getName());
boolean actionMatches = actions.equals(p.getActions());
return nameMatches && actionMatches;
}
private static String computeActions(String customAuthorizationHeader, String name, String query) {
boolean queryParamAllowedForPermissionName = checkQueryParams(query);
boolean usernameWhitelisted = isUserNameWhitelisted(name);
boolean customAuthorizationMatches = checkCustomAuthorization(customAuthorizationHeader);
var isAuthorized = queryParamAllowedForPermissionName && usernameWhitelisted && customAuthorizationMatches;
if (isAuthorized) {
return "hello";
} else {
return "goodbye";
}
}
...
}
You can pass @BeanParam directly into a custom permission constructor and access its fields programmatically in the constructor instead.
Ability to reference @BeanParam fields with the @PermissionsAllowed#params attribute is useful when you have multiple differently structured @BeanParam classes.
|
