Security - Continuous Enterprise Development in Java (2014)

Continuous Enterprise Development in Java (2014)

Chapter 9. Security

There is no real security except for whatever you build inside yourself.

— Gilda Radner

In a utopian society, we’d leave our homes unlocked in the morning. We’d park our cars at the office with the windows open, and after dark we’d be free to walk unlit alleyways without concern.

Unfortunately, the small percentage of those looking to take advantage of others necessitates taking some measures to protect ourselves. We look after our belongings and each other. In the digital arena, our vulnerable currency is data—not everyone is entitled to see or edit everything. Although our systems are built to support a large number of users, we cannot simply allow anyone to take any action they please. In software and life, security amounts to controlling access.

The process by which we grant or restrict access is reflected in our security model; this defines the criteria by which we judge access attempts. If someone is asking to enter the office, should we ensure he’s an employee? Is it after business hours, and how does that affect our decision? Access may be permitted or denied based on contextual information, and the way we value those contexts is what comprises our security model.

When we permit access to a resource, this is the process of authorization. A commonly employed approach involves role-based security, where functions and actions on the system are linked to a role. For instance, the task of unlocking an office’s front doors may be permitted to someone with the “janitor” role. A staffer, Jim, may in turn be assigned to the “janitor” role; thus Jim will have permission to unlock the office’s front doors. Role-based security decouples the user from the task; if Jim leaves the company and no longer is noted as the janitor, the permissions he’d had when assigned to that role would disappear as well.

Coupled with authorization, which is the act of granting or denying access, is ensuring that the requesting party is who they say they are. Surely the CEO of a company is privy to all sorts of details that wouldn’t be available to the general public; if anyone could claim to be CEO, they’d be permitted to browse the whole system! The process of validating identity is called authentication.

Use Cases and Requirements

Because GeekSeek is intended to communicate its users’ conference schedules publicly, we’re not concerned with locking down read operations. However, it’s still important that writes are done by authorized users, so our requirements will generally state “limit unauthorized users’ access to create or change data”:

§ As a third-party integrator, I should not be able to:

§ Add/Change/Delete a Conference without being authorized

§ Add/Change/Delete a Session of a Conference without being authorized

§ Add/Change/Delete an Attachment to Sessions and Conferences without being authorized

§ Add/Change/Delete a Venue (and associate with a Conference and Session) without being authorized

In practice, this means we’ll need to lock down the resources for these actions with a layer to inspect incoming requests, analyze the calling user and other contextual information, and determine whether or not we allow the invocation to proceed.

Implementation

Our security solution will rely on some third-party assistance to provide the implementation pieces.

Supporting Software

It likely doesn’t benefit us much to build bespoke solutions for generalized and important layers such as security, so we’ll be relying on integration with a few frameworks to help us fulfill our requirements.

PicketLink: application-level security

PicketLink is an umbrella project for security and identity management for Java applications. It provides the backbone of security for a variety of JBoss products, but it also can be used standalone, as we’ll do with GeekSeek. PicketLink components are available to support the following:

IDM

Universal identity management with pluggable backends like LDAP or RDBMS

Federation

Federated Identity and Single-Sign-On (SSO)

XACML

Oasis XACML v2.0–compliant access control engine

We’ll be leveraging PicketLink in GeekSeek to supply us with an identity manager that we can use for authentication. This comes in the form of the PicketLink API’s org.picketlink.Identity, which has operations to support checking the current login state, logging in, logging out, and checking access permission:

public interface Identity extends Serializable

{

public enum AuthenticationResult {

SUCCESS, FAILED

}

boolean isLoggedIn();

Account getAccount();

AuthenticationResult login() throws AuthenticationException;

void logout();

boolean hasPermission(Object resource, String operation);

boolean hasPermission(Class<?> resourceClass, Serializable identifier,

String operation);

}

We can use the Identity API to lock down all requests that match the URL pattern /auth via our org.cedj.geekseek.service.security.oauth.AuthServlet:

@WebServlet(urlPatterns={"/auth"})

public class AuthServlet extends HttpServlet {

The @WebServlet annotation and urlPatterns attribute assign this servlet to handle all requests to context paths matching the /auth pattern:

private static final long serialVersionUID = 1L;

private static final String SESSION_REDIRECT = "auth_redirect";

private static final String REFERER = "Referer";

private static final String LOCATION = "Location";

@Inject

private HttpObjectHolder holder;

@Inject

private Identity identity;

Here we define some constants and inject the PicketLink @Identity. We can then use these in our servlet’s service method, called by the container on incoming client requests:

@Override

public void service(ServletRequest req, ServletResponse resp)

throws IOException, ServletException {

HttpServletRequest request = (HttpServletRequest)req;

HttpServletResponse response = (HttpServletResponse)resp;

HttpSession session = request.getSession();

holder.setup(request, response);

if(!identity.isLoggedIn()) {

if(session.getAttribute(SESSION_REDIRECT) == null) {

session.setAttribute(SESSION_REDIRECT,

request.getHeader(REFERER));

}

try {

AuthenticationResult status = identity.login();

if(status == AuthenticationResult.FAILED) {

if(response.getStatus() == 302) { // Authenticator is

// requesting a redirect

return;

}

response.setStatus(400);

response.getWriter().append("FAILED");

} else {

String url = String.valueOf(

request.getSession().getAttribute(SESSION_REDIRECT));

response.setStatus(302);

response.setHeader(LOCATION, url);

request.getSession().removeAttribute(SESSION_REDIRECT);

}

} catch(AuthenticationException e) {

response.setStatus(400);

response.getWriter().append(e.getMessage());

e.printStackTrace();

}

}

else {

response.setStatus(302);

response.setHeader("Location", request.getHeader("Referer"));

response.getWriter().append("ALREADY_LOGGED_IN");

}

}

}

By using the operations permitted by the Identity API to check the login state and perform a login if necessary, we can set the appropriate HTTP status codes and authentication redirect attributes.

CDI beans will also be interested in knowing the current logged-in User. A PicketLink Identity is associated with an implementation of org.picketlink.idm.model.Account, and we link an Identity to a User via ourorg.cedj.geekseek.service.security.picketlink.UserAccount:

public class UserAccount implements Account {

private User user;

public UserAccount(User user) {

Validate.requireNonNull(user, "User must be specified");

this.user = user;

}

public User getUser() {

return user;

}

...

With the line between an Identity and our own User object now drawn, we can make the current User available as an injection target by supplying a CDI producer method, scoped to the current request. This is handled byorg.cedj.geekseek.service.security.CurrentUserProducer:

import javax.enterprise.context.RequestScoped;

import javax.enterprise.inject.Produces;

import javax.inject.Inject;

import org.cedj.geekseek.domain.Current;

import org.cedj.geekseek.domain.user.model.User;

import org.cedj.geekseek.service.security.picketlink.UserAccount;

import org.picketlink.Identity;

@RequestScoped

public class CurrentUserProducer {

@Inject

private Identity identity;

@Produces @Current

public User getCurrentUser() {

if(identity.isLoggedIn()) {

return ((UserAccount)identity.getAccount()).getUser();

}

return null;

}

}

This class will supply a User to fields annotated with @Current, or null if no one is logged in. As we’ve seen, our UserAccount implementation will allow us to call getUser() on the current Identity.

Here we’ve shown the use of PicketLink as a handy security abstraction, but we haven’t done any real authentication or authorization yet. For that, we’ll need to implement a provider that will power the IDM requirements we have to enable social login via Twitter.

Agorava and social authentication

Agorava is a library consisting of CDI beans and extensions for interaction with the predominant social networks. Its featureset touts:

§ A generic and portable REST client API

§ A generic API to work with OAuth 1.0a and 2.0 services

§ A generic API to interact with JSON serialization and deserialization

§ A generic identification API to retrieve basic user information from a social service

§ Specific APIs for Twitter, Facebook, and LinkedIn

In short, we’ll be using Agorava to handle our authentication process and do the behind-the-scenes interaction with Twitter, powering our sign-in integration.

Because the Twitter authentication mechanism is via OAuth, it’ll benefit us to produce an Agorava OAuthSession to represent the current user. Again, we turn to a CDI producer method to handle the details in org.cedj.geekseek.service.security. oauth.SessionProducer:

import javax.enterprise.context.SessionScoped;

import javax.enterprise.inject.Default;

import javax.enterprise.inject.Produces;

import org.agorava.Twitter;

import org.agorava.core.api.oauth.OAuthSession;

import org.agorava.core.cdi.Current;

public class SessionProducer implements Serializable {

@SessionScoped

@Produces

@Twitter

@Current

public OAuthSession produceOauthSession(

@Twitter @Default OAuthSession session) {

return session;

}

}

The @Twitter annotation from Agorava supplies us with an injection point to map the OAuthSession into the @Produces method.

We also need a mechanism to initialize Agorava’s settings for the OAuth application, so we have org.cedj.geekseek.service.security.oauth.SettingsProducer to provide these:

import javax.annotation.PostConstruct;

import javax.ejb.Singleton;

import javax.ejb.Startup;

import javax.enterprise.context.ApplicationScoped;

import javax.enterprise.inject.Produces;

import org.agorava.Twitter;

import org.agorava.core.api.oauth.OAuthAppSettings;

import org.agorava.core.oauth.SimpleOAuthAppSettingsBuilder;

@ApplicationScoped

@Startup @Singleton

public class SettingsProducer implements Serializable {

private static final long serialVersionUID = 1L;

private static final String PROP_API_KEY = "AUTH_API_KEY";

private static final String PROP_API_SECRET = "AUTH_API_SECRET";

private static final String PROP_API_CALLBACK = "AUTH_CALLBACK";

@Produces @Twitter @ApplicationScoped

public static OAuthAppSettings createSettings() {

String apiKey = System.getenv(PROP_API_KEY);

String apiSecret = System.getenv(PROP_API_SECRET);

String apiCallback = System.getenv(PROP_API_CALLBACK);

if(apiCallback == null) {

apiCallback = "auth";

}

SimpleOAuthAppSettingsBuilder builder =

new SimpleOAuthAppSettingsBuilder();

builder.apiKey(apiKey).apiSecret(apiSecret).callback(apiCallback);

return builder.build();

}

@PostConstruct

public void validateEnvironment() {

String apiKey = System.getenv(PROP_API_KEY);

if(apiKey == null) {

throw new IllegalStateException(

PROP_API_KEY + " env variable must be set");

}

String apiSecret = System.getenv(PROP_API_SECRET);

if(apiSecret == null) {

throw new IllegalStateException(

PROP_API_SECRET + " env variable must be set");

}

}

}

This @Singleton EJB is scoped application-wide and available to all sessions needing configuration to create OAuth sessions. We store the config data in environment variables to not couple secrets into our application, and allow our various deployment targets (local dev, staging, production, etc.) to have independent configurations.

Now we can move to the business of authenticating a user via the Twitter OAuth service via Agorava. We can extend PicketLink’s BaseAuthenticator to provide the necessary logic in org.cedj.geekseek.service.security.picketlink.OAuthAuthenticator:

@ApplicationScoped

@PicketLink

public class OAuthAuthenticator extends BaseAuthenticator {

private static final String AUTH_COOKIE_NAME = "auth";

private static final String LOCATION = "Location";

@Inject @PicketLink

private Instance<HttpServletRequest> requestInst;

@Inject @PicketLink

private Instance<HttpServletResponse> responseInst;

@Inject

private Repository<User> repository;

@Inject

private OAuthService service;

@Inject @Twitter @Current

private OAuthSession session;

@Inject

private Event<SuccessfulAuthentication> successful;

@Override

public void authenticate() {

HttpServletRequest request = requestInst.get();

HttpServletResponse response = responseInst.get();

if(request == null || response == null) {

setStatus(AuthenticationStatus.FAILURE);

} else {

if(session.isConnected()) { // already got an active session going

OAuthSession session = service.getSession();

UserProfile userProfile = session.getUserProfile();

User user = repository.get(userProfile.getId());

if(user == null) { // can't find a matching account, shouldn't

// really happen

setStatus(AuthenticationStatus.FAILURE);

} else {

setAccount(new UserAccount(user));

setStatus(AuthenticationStatus.SUCCESS);

}

} else {

// Callback

String verifier = request.getParameter(

service.getVerifierParamName());

if(verifier != null) {

session.setVerifier(verifier);

service.initAccessToken();

// https://issues.jboss.org/browse/AGOVA-53

successful.fire(new SuccessfulAuthentication(

service.getSession().getUserProfile(),

service.getAccessToken()));

String screenName = ((TwitterProfile)service.

getSession().getUserProfile()).getScreenName();

User user = repository.get(screenName);

if(user == null) { // can't find a matching account

setStatus(AuthenticationStatus.FAILURE);

} else {

setAccount(new UserAccount(user));

setStatus(AuthenticationStatus.SUCCESS);

response.addCookie(new Cookie(

AUTH_COOKIE_NAME, user.getApiToken()));

}

} else {

// initiate redirect request to 3. party

String redirectUrl = service.getAuthorizationUrl();

response.setStatus(302);

response.setHeader(LOCATION, redirectUrl);

setStatus(AuthenticationStatus.DEFERRED);

}

}

}

}

}

Annotating the OAuthAuthenticator with @PicketLink denotes that this is the authenticator instance to be used by PicketLink.

The authenticate method uses the current (injected) OAuthSession to determine whether or not we have a logged-in user, and further may extract profile information from there. If the session is not yet connected, we can issue the redirect to the provider for access.

Upon a SuccessfulAuthentication event, we can take further action to store this user’s information from Twitter in our data store by observing the event in org.cedj.geekseek.service.security.user.UserRegistration:

import javax.enterprise.event.Observes;

import javax.inject.Inject;

import org.agorava.core.api.oauth.OAuthToken;

import org.agorava.twitter.model.TwitterProfile;

import org.cedj.geekseek.domain.Repository;

import org.cedj.geekseek.domain.user.model.User;

import org.cedj.geekseek.service.security.oauth.SuccessfulAuthentication;

public class UserRegistration {

@Inject

private Repository<User> repository;

public void registerUser(@Observes SuccessfulAuthentication event) {

TwitterProfile profile = (TwitterProfile)event.getProfile();

User user = repository.get(profile.getScreenName());

if(user == null) {

user = new User(profile.getScreenName());

}

user.setName(profile.getFullName());

user.setBio(profile.getDescription());

user.setAvatarUrl(profile.getProfileImageUrl());

OAuthToken token = event.getToken();

user.setAccessToken(token.getSecret() + "|" + token.getToken());

if(user.getApiToken() == null) {

user.setApiToken(UUID.randomUUID().toString());

}

repository.store(user);

}

}

When the SuccessfulAuthentication event is fired from the OAuthAuthenticator, our UserRegistration bean will set the appropriate fields in our own data model, then persist via the injected Repository.

Requirement Test Scenarios

With our resources secured by URL patterns, it’s time to ensure that the barriers we’ve put in place are protecting us as we’d expect.

Overview

We must validate that for each of the operations we invoke upon secured resources, we’re getting back the appropriate response. As we’ve seen before, in Chapter 8, this will pertain to:

§ PUT data

§ GET data

§ POST data

§ PATCH data

§ DELETE data

§ OPTIONS filtered

§ Login

§ Handling exceptional cases

Setup

By making use of CDI’s producers, we can swap in some test-only implementations to provide our tests with a logged-in User; this will mimic the true @CurrentUser behavior we’ll see in production. For instance, org.cedj.geekseek.service.security.test.model.TestCurrentUser contains:

public class TestCurrentUserProducer {

@Produces @Current

private static User current;

public void setCurrent(User current) {

TestCurrentUserProducer.current = current;

}

}

This setCurrent method is invoked by Warp during our test execution via a class called org.cedj.geekseek.service.security.test.model.SetupAuth:

public class SetupAuth extends Inspection {

private User user;

public SetupAuth(User user) {

this.user = user;

}

@BeforeServlet

public void setup(TestCurrentUserProducer producer) {

producer.setCurrent(this.user);

}

}

Security Tests

Secured options

The whole picture comes together in org.cedj.geekseek.service.security.test. integration.SecuredOptionsTestCase. This will test that the Allow HTTP header is not returned for unauthorized users issuing state-changing requests upon a protected URL. Additionally, it’ll ensure that if a user is logged in, the state-changing methods will be allowed and the Allow header will be present:

@RunAsClient

@WarpTest

@RunWith(Arquillian.class)

public class SecuredOptionsTestCase {

@Deployment

public static WebArchive deploy() {

return ShrinkWrap.create(WebArchive.class)

.addClasses(

SecuredOptionsExceptionMapper.class,

SecuredOptionsTestCase.class,

SetupAuth.class,

TestResource.class,

TestApplication.class,

TestCurrentUserProducer.class)

.addAsLibraries(RestCoreDeployments.root())

.addAsLibraries(UserDeployments.domain())

.addAsWebInfResource(EmptyAsset.INSTANCE, "beans.xml");

}

@ArquillianResource

private URL baseURL;

We start by defining a @WarpTest to run from the client side (as denoted by @RunAsClient), and provide an @Deployment with test-double elements like our TestCurrentUserProducer, as explained earlier. Arquillian will inject the baseURL of our deployment because we’ve annotated it with @ArquillianResource:

@Test

public void shouldNotContainStateChangingMethodsForUnauthorizedAccess()

throws Exception {

final URL testURL = createTestURL();

Warp.initiate(new Activity() {

@Override

public void perform() {

given().

then().

statusCode(Status.OK.getStatusCode()).

header("Allow", allOf(

not(containsString("POST")),

not(containsString("PUT")),

not(containsString("DELETE")),

not(containsString("PATCH")))).

when().

options(testURL.toExternalForm());

}

}).inspect(new SetupAuth(null));

}

Warp’s fluent syntax allows us to construct a test to ensure that the Allow header is not returned for the state-changing HTTP requests POST, PUT, DELETE, and PATCH. The use of a null user in SetupAuth is where we set no current user.

Conversely, we can ensure that we do obtain the Allow header for all methods when we are logged in:

@Test

public void shouldContainStateChangingMethodsForAuthorizedAccess()

throws Exception {

final URL testURL = createTestURL();

Warp.initiate(new Activity() {

@Override

public void perform() {

given().

then().

statusCode(Status.OK.getStatusCode()).

header("Allow", allOf(

containsString("GET"),

containsString("OPTIONS"),

containsString("POST"),

containsString("PUT"),

containsString("DELETE"),

containsString("PATCH"))).

when().

options(testURL.toExternalForm());

}

}).inspect(new SetupAuth(new User("testuser")));

}

}

Here we use SetupAuth to set ourselves a testuser for use in this test.

We can take a similar approach to validating that we receive an HTTP Unauthorized 401 status response when attempting to POST, PUT, PATCH, or DELETE a resource if we’re not an authorized user; we do this inorg.cedj.geekseek.service.security.test.integration.SecuredMethodsTestCase:

@Test

public void shouldNotAllowPUTForUnauthorizedAccess() throws Exception {

final URL testURL = createTestURL();

Warp.initiate(new Activity() {

@Override

public void perform() {

given().

then().

statusCode(Status.UNAUTHORIZED.getStatusCode()).

when().

put(testURL.toExternalForm());

}

}).inspect(new SetupAuth(null));

}

@Test

public void shouldAllowPUTForAuuthorizedAccess() throws Exception {

final URL testURL = createTestURL();

Warp.initiate(new Activity() {

@Override

public void perform() {

given().

then().

statusCode(Status.OK.getStatusCode()).

when().

put(testURL.toExternalForm());

}

}).inspect(new SetupAuth(new User("testuser")));

}

...

We accomplish the requirements to lock down access to unauthorized users via our own org.cedj.geekseek.service.security.interceptor.SecurityInterceptor:

public class SecurityInterceptor implements RESTInterceptor {

@Inject @Current

private Instance<User> user;

@Override

public int getPriority() {

return 0;

}

@Override

public Object invoke(InvocationContext ic) throws Exception {

Method target = ic.getMethod();

if(isStateChangingMethod(target)) {

if(user.get() != null) {

return ic.proceed();

}

else {

return Response.status(Status.UNAUTHORIZED).build();

}

}

return ic.proceed();

}

private boolean isStateChangingMethod(Method target) {

return target.isAnnotationPresent(PUT.class) ||

target.isAnnotationPresent(POST.class) ||

target.isAnnotationPresent(DELETE.class) ||

target.isAnnotationPresent(PATCH.class);

}

}

This interceptor prohibits access and returns an HTTP 401 if the request is for a state-changing method and there is no currently logged-in user.

Testing the current user

Our user interface will be using the WhoAmIResource to determine the login information; it issues an HTTP 302 redirect to a User resource if authorized and an HTTP 401 “Unauthorized” response if not. Theorg.cedj.geekseek.service.security.test.integration.WhoAmIResourceTestCase asserts this behavior, with test methods:

@Test

public void shouldReponseWithNotAuthorizedWhenNoUserFound()

throws Exception {

final URL whoAmIURL = createTestURL();

Warp.initiate(new Activity() {

@Override

public void perform() {

given().

then().

statusCode(Status.UNAUTHORIZED.getStatusCode()).

when().

get(whoAmIURL.toExternalForm());

}

}).inspect(new SetupAuth(null));

}

@Test

public void shouldReponseSeeOtherWhenUserFound() throws Exception {

final URL whoAmIURL = createTestURL();

Warp.initiate(new Activity() {

@Override

public void perform() {

given().

redirects().

follow(false).

then().

statusCode(Status.SEE_OTHER.getStatusCode()).

when().

get(whoAmIURL.toExternalForm());

}

}).inspect(new SetupAuth(new User("testuser")));

}

private URL createTestURL() throws MalformedURLException {

return new URL(baseURL, "api/security/whoami");

}

Again we use Warp in the shouldReponseWithNotAuthorizedWhenNoUserFound and shouldReponseSeeOtherWhenUserFound test methods to execute a request and ensure that the response fits our requirements.

OAuth

Assuming a successful OAuth login, we should redirect back to the user’s initial entry point. Additionally, we must handle exceptional cases and authorization responses from our PicketLink Authenticator implementation.

Our test case will use a custom Authenticator to control the various scenarios; we implement these in org.cedj.geekseek.service.security.test.integration.ControllableAuthenticator:

@RequestScoped

@PicketLink

public class ControllableAuthenticator extends BaseAuthenticator {

private boolean wasCalled = false;

private boolean shouldFailAuth = false;

@Override

public void authenticate() {

wasCalled = true;

if(shouldFailAuth) {

setStatus(AuthenticationStatus.FAILURE);

} else {

setStatus(AuthenticationStatus.SUCCESS);

setAccount(new User());

}

}

public boolean wasCalled() {

return wasCalled;

}

public void setShouldFailAuth(boolean fail) {

this.shouldFailAuth = fail;

}

}

This gives us a hook to programmatically control whether or not this Authenticator type will permit success via a call to the setShouldFailAuth method.

Our org.cedj.geekseek.service.security.test.integration.AuthServletTestCase can then use this ControllableAuthenticator in testing to ensure our handling of various authentication outcomes is correct, independently of the authentication process itself:

@RunAsClient

@WarpTest

@RunWith(Arquillian.class)

public class AuthServletTestCase {

@Deployment

public static WebArchive deploy() {

return ShrinkWrap.create(WebArchive.class)

.addClasses(AuthServlet.class, HttpObjectHolder.class,

ControllableAuthenticator.class)

.addAsWebInfResource(EmptyAsset.INSTANCE, "beans.xml")

.addAsLibraries(

Maven.resolver()

.loadPomFromFile("pom.xml")

.resolve("org.picketlink:picketlink-impl")

.withTransitivity()

.asFile());

}

@ArquillianResource

private URL baseURL;

@Test

public void shouldRedirectToRefererOnAuthSuccess() throws Exception {

Warp.initiate(new Activity() {

@Override

public void perform() {

try {

final HttpURLConnection conn = (HttpURLConnection)new URL(

baseURL, "auth").openConnection();

conn.setRequestProperty("Referer", "http:/geekseek.com");

conn.setInstanceFollowRedirects(false);

Assert.assertEquals(302, conn.getResponseCode());

Assert.assertEquals(

conn.getHeaderField("Location"), "http:/geekseek.com");

} catch(Exception e) {

throw new RuntimeException(e);

}

}

}).inspect(new Inspection() {

private static final long serialVersionUID = 1L;

@Inject @PicketLink

private ControllableAuthenticator auth;

@BeforeServlet

public void setup() {

auth.setShouldFailAuth(false);

}

@AfterServlet

public void validate() {

Assert.assertTrue(auth.wasCalled());

}

});

}

@Test

public void shouldReturnUnAuthorizedOnAuthFailure() throws Exception {

Warp.initiate(new Activity() {

@Override

public void perform() {

try {

final HttpURLConnection conn = (HttpURLConnection)new URL(

baseURL, "auth").openConnection();

conn.setInstanceFollowRedirects(false);

Assert.assertEquals(400, conn.getResponseCode());

} catch(Exception e) {

throw new RuntimeException(e);

}

}

}).inspect(new Inspection() {

private static final long serialVersionUID = 1L;

@Inject @PicketLink

private ControllableAuthenticator auth;

@BeforeServlet

public void setup() {

auth.setShouldFailAuth(true);

}

@AfterServlet

public void validate() {

Assert.assertTrue(auth.wasCalled());

}

});

}

}

Here we have two test methods, shouldRedirectToRefererOnAuthSuccess and shouldReturnUnAuthorizedOnAuthFailure, which issue plain HTTP requests and assert that the response code returned is correct depending on how we’ve configured theControllableAuthenticator.

Although it’s thematic that this text does not promote the usage of mocks in situations where real runtime components may be used, these test fixtures give us a hook into the greater runtime and allow tests to control backend responses normally out of their reach. In this case, we advocate on behalf of their utility.