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Google Auth Library

Open source authentication client library for Java.

stable Maven

This project consists of 3 artifacts:

Table of contents:

Quickstart

If you are using Maven, add this to your pom.xml file (notice that you can replace google-auth-library-oauth2-http with any of google-auth-library-credentials and google-auth-library-appengine, depending on your application needs):

<dependency>
  <groupId>com.google.auth</groupId>
  <artifactId>google-auth-library-oauth2-http</artifactId>
  <version>1.19.0</version>
</dependency>

If you are using Gradle, add this to your dependencies

implementation 'com.google.auth:google-auth-library-oauth2-http:1.19.0'

If you are using SBT, add this to your dependencies

libraryDependencies += "com.google.auth" % "google-auth-library-oauth2-http" % "1.19.0"

google-auth-library-oauth2-http

Application Default Credentials

This library provides an implementation of Application Default Credentials for Java. Application Default Credentials provide a simple way to get authorization credentials for use in calling Google APIs.

They are best suited for cases when the call needs to have the same identity and authorization level for the application independent of the user. This is the recommended approach to authorize calls to Cloud APIs, particularly when you're building an application that uses Google Cloud Platform.

Application Default Credentials also support workload identity federation to access Google Cloud resources from non-Google Cloud platforms including Amazon Web Services (AWS), Microsoft Azure or any identity provider that supports OpenID Connect (OIDC). Workload identity federation is recommended for non-Google Cloud environments as it avoids the need to download, manage and store service account private keys locally, see: Workload Identity Federation.

Getting Application Default Credentials

To get Application Default Credentials use GoogleCredentials.getApplicationDefault() or GoogleCredentials.getApplicationDefault(HttpTransportFactory). These methods return the Application Default Credentials which are used to identify and authorize the whole application. The following are searched (in order) to find the Application Default Credentials:

  1. Credentials file pointed to by the GOOGLE_APPLICATION_CREDENTIALS environment variable
  2. Credentials provided by the Google Cloud SDK gcloud auth application-default login command
  3. Google App Engine built-in credentials
  4. Google Cloud Shell built-in credentials
  5. Google Compute Engine built-in credentials
    • Skip this check by setting the environment variable NO_GCE_CHECK=true
    • Customize the GCE metadata server address by setting the environment variable GCE_METADATA_HOST=<hostname>

Explicit Credential Loading

To get Credentials from a Service Account JSON key use GoogleCredentials.fromStream(InputStream) or GoogleCredentials.fromStream(InputStream, HttpTransportFactory). Note that the credentials must be refreshed before the access token is available.

GoogleCredentials credentials = GoogleCredentials.fromStream(new FileInputStream("/path/to/credentials.json"));
credentials.refreshIfExpired();
AccessToken token = credentials.getAccessToken();
// OR
AccessToken token = credentials.refreshAccessToken();

ImpersonatedCredentials

Allows a credentials issued to a user or service account to impersonate another. The source project using ImpersonatedCredentials must enable the "IAMCredentials" API. Also, the target service account must grant the orginating principal the "Service Account Token Creator" IAM role.

String credPath = "/path/to/svc_account.json";
ServiceAccountCredentials sourceCredentials = ServiceAccountCredentials
     .fromStream(new FileInputStream(credPath));
sourceCredentials = (ServiceAccountCredentials) sourceCredentials
    .createScoped(Arrays.asList("https://www.googleapis.com/auth/iam"));

ImpersonatedCredentials targetCredentials = ImpersonatedCredentials.create(sourceCredentials,
    "impersonated-account@project.iam.gserviceaccount.com", null,
    Arrays.asList("https://www.googleapis.com/auth/devstorage.read_only"), 300);

Storage storage_service = StorageOptions.newBuilder().setProjectId("project-id")
    .setCredentials(targetCredentials).build().getService();

for (Bucket b : storage_service.list().iterateAll())
    System.out.println(b); 

Workload Identity Federation

Using workload identity federation, your application can access Google Cloud resources from Amazon Web Services (AWS), Microsoft Azure, or any identity provider that supports OpenID Connect (OIDC).

Traditionally, applications running outside Google Cloud have used service account keys to access Google Cloud resources. Using identity federation, your workload can impersonate a service account. This lets the external workload access Google Cloud resources directly, eliminating the maintenance and security burden associated with service account keys.

Accessing resources from AWS

In order to access Google Cloud resources from Amazon Web Services (AWS), the following requirements are needed:

Follow the detailed instructions on how to configure workload identity federation from AWS.

After configuring the AWS provider to impersonate a service account, a credential configuration file needs to be generated. Unlike service account credential files, the generated credential configuration file contains non-sensitive metadata to instruct the library on how to retrieve external subject tokens and exchange them for service account access tokens. The configuration file can be generated by using the gcloud CLI.

To generate the AWS workload identity configuration, run the following command:

# Generate an AWS configuration file.
gcloud iam workload-identity-pools create-cred-config \
    projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$POOL_ID/providers/$AWS_PROVIDER_ID \
    --service-account $SERVICE_ACCOUNT_EMAIL \
    --aws \
    --output-file /path/to/generated/config.json

Where the following variables need to be substituted:

This generates the configuration file in the specified output file.

If you are using AWS IMDSv2, an additional flag --enable-imdsv2 needs to be added to the gcloud iam workload-identity-pools create-cred-config command:

gcloud iam workload-identity-pools create-cred-config \
    projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$POOL_ID/providers/$AWS_PROVIDER_ID \
    --service-account $SERVICE_ACCOUNT_EMAIL \
    --aws \
    --output-file /path/to/generated/config.json \
    --enable-imdsv2

You can now use the Auth library to call Google Cloud resources from AWS.

Access resources from Microsoft Azure

In order to access Google Cloud resources from Microsoft Azure, the following requirements are needed:

Follow the detailed instructions on how to configure workload identity federation from Microsoft Azure.

After configuring the Azure provider to impersonate a service account, a credential configuration file needs to be generated. Unlike service account credential files, the generated credential configuration file contains non-sensitive metadata to instruct the library on how to retrieve external subject tokens and exchange them for service account access tokens. The configuration file can be generated by using the gcloud CLI.

To generate the Azure workload identity configuration, run the following command:

# Generate an Azure configuration file.
gcloud iam workload-identity-pools create-cred-config \
    projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$POOL_ID/providers/$AZURE_PROVIDER_ID \
    --service-account $SERVICE_ACCOUNT_EMAIL \
    --azure \
    --output-file /path/to/generated/config.json

Where the following variables need to be substituted:

This generates the configuration file in the specified output file.

You can now use the Auth library to call Google Cloud resources from Azure.

Accessing resources from an OIDC identity provider

In order to access Google Cloud resources from an identity provider that supports OpenID Connect (OIDC), the following requirements are needed:

Follow the detailed instructions on how to configure workload identity federation from an OIDC identity provider.

After configuring the OIDC provider to impersonate a service account, a credential configuration file needs to be generated. Unlike service account credential files, the generated credential configuration file contains non-sensitive metadata to instruct the library on how to retrieve external subject tokens and exchange them for service account access tokens. The configuration file can be generated by using the gcloud CLI.

For OIDC providers, the Auth library can retrieve OIDC tokens either from a local file location (file-sourced credentials) or from a local server (URL-sourced credentials).

File-sourced credentials For file-sourced credentials, a background process needs to be continuously refreshing the file location with a new OIDC token prior to expiration. For tokens with one hour lifetimes, the token needs to be updated in the file every hour. The token can be stored directly as plain text or in JSON format.

To generate a file-sourced OIDC configuration, run the following command:

# Generate an OIDC configuration file for file-sourced credentials.
gcloud iam workload-identity-pools create-cred-config \
    projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$POOL_ID/providers/$OIDC_PROVIDER_ID \
    --service-account $SERVICE_ACCOUNT_EMAIL \
    --credential-source-file $PATH_TO_OIDC_ID_TOKEN \
    # Optional arguments for file types. Default is "text":
    # --credential-source-type "json" \
    # Optional argument for the field that contains the OIDC credential.
    # This is required for json.
    # --credential-source-field-name "id_token" \
    --output-file /path/to/generated/config.json

Where the following variables need to be substituted:

This generates the configuration file in the specified output file.

URL-sourced credentials For URL-sourced credentials, a local server needs to host a GET endpoint to return the OIDC token. The response can be in plain text or JSON. Additional required request headers can also be specified.

To generate a URL-sourced OIDC workload identity configuration, run the following command:

# Generate an OIDC configuration file for URL-sourced credentials.
gcloud iam workload-identity-pools create-cred-config \
    projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$POOL_ID/providers/$OIDC_PROVIDER_ID \
    --service-account $SERVICE_ACCOUNT_EMAIL \
    --credential-source-url $URL_TO_GET_OIDC_TOKEN \
    --credential-source-headers $HEADER_KEY=$HEADER_VALUE \
    # Optional arguments for file types. Default is "text":
    # --credential-source-type "json" \
    # Optional argument for the field that contains the OIDC credential.
    # This is required for json.
    # --credential-source-field-name "id_token" \
    --output-file /path/to/generated/config.json

Where the following variables need to be substituted:

You can now use the Auth library to call Google Cloud resources from an OIDC provider.

Using Executable-sourced credentials with OIDC and SAML

Executable-sourced credentials For executable-sourced credentials, a local executable is used to retrieve the 3rd party token. The executable must handle providing a valid, unexpired OIDC ID token or SAML assertion in JSON format to stdout.

To use executable-sourced credentials, the GOOGLE_EXTERNAL_ACCOUNT_ALLOW_EXECUTABLES environment variable must be set to 1.

To generate an executable-sourced workload identity configuration, run the following command:

# Generate a configuration file for executable-sourced credentials.
gcloud iam workload-identity-pools create-cred-config \
    projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$POOL_ID/providers/$PROVIDER_ID \
    --service-account=$SERVICE_ACCOUNT_EMAIL \
    --subject-token-type=$SUBJECT_TOKEN_TYPE \
    # The absolute path for the program, including arguments.
    # e.g. --executable-command="/path/to/command --foo=bar"
    --executable-command=$EXECUTABLE_COMMAND \
    # Optional argument for the executable timeout. Defaults to 30s.
    # --executable-timeout-millis=$EXECUTABLE_TIMEOUT \
    # Optional argument for the absolute path to the executable output file.
    # See below on how this argument impacts the library behaviour.
    # --executable-output-file=$EXECUTABLE_OUTPUT_FILE \
    --output-file /path/to/generated/config.json

Where the following variables need to be substituted:

The --executable-timeout-millis flag is optional. This is the duration for which the auth library will wait for the executable to finish, in milliseconds. Defaults to 30 seconds when not provided. The maximum allowed value is 2 minutes. The minimum is 5 seconds.

The --executable-output-file flag is optional. If provided, the file path must point to the 3PI credential response generated by the executable. This is useful for caching the credentials. By specifying this path, the Auth libraries will first check for its existence before running the executable. By caching the executable JSON response to this file, it improves performance as it avoids the need to run the executable until the cached credentials in the output file are expired. The executable must handle writing to this file - the auth libraries will only attempt to read from this location. The format of contents in the file should match the JSON format expected by the executable shown below.

To retrieve the 3rd party token, the library will call the executable using the command specified. The executable's output must adhere to the response format specified below. It must output the response to stdout.

A sample successful executable OIDC response:

{
  "version": 1,
  "success": true,
  "token_type": "urn:ietf:params:oauth:token-type:id_token",
  "id_token": "HEADER.PAYLOAD.SIGNATURE",
  "expiration_time": 1620499962
}

A sample successful executable SAML response:

{
  "version": 1,
  "success": true,
  "token_type": "urn:ietf:params:oauth:token-type:saml2",
  "saml_response": "...",
  "expiration_time": 1620499962
}

A sample executable error response:

{
  "version": 1,
  "success": false,
  "code": "401",
  "message": "Caller not authorized."
}

These are all required fields for an error response. The code and message fields will be used by the library as part of the thrown exception.

For successful responses, the expiration_time field is only required when an output file is specified in the credential configuration.

Response format fields summary:

All response types must include both the version and success fields.

The library will populate the following environment variables when the executable is run:

These environment variables can be used by the executable to avoid hard-coding these values.

Security considerations

The following security practices are highly recommended:

Given the complexity of using executable-sourced credentials, it is recommended to use the existing supported mechanisms (file-sourced/URL-sourced) for providing 3rd party credentials unless they do not meet your specific requirements.

You can now use the Auth library to call Google Cloud resources from an OIDC or SAML provider.

Using a custom supplier with OIDC and SAML

A custom implementation of IdentityPoolSubjectTokenSupplier can be used while building IdentityPoolCredentials to supply a subject token which can be exchanged for a GCP access token. The supplier must return a valid, unexpired subject token when called by the GCP credential.

IdentityPoolCredentials do not cache the returned token, so caching logic should be implemented in the token supplier to prevent multiple requests for the same subject token.

import java.io.IOException;

public class CustomTokenSupplier implements IdentityPoolSubjectTokenSupplier {

  @Override
  public String getSubjectToken(ExternalAccountSupplierContext context) throws IOException {
    // Any call to the supplier will pass a context object with the requested
    // audience and subject token type.
    string audience = context.getAudience();
    string tokenType = context.getSubjectTokenType();

    try {
      // Return a valid, unexpired token for the requested audience and token type.
      // Note that IdentityPoolCredentials do not cache the subject token so
      // any caching logic needs to be implemented in the token supplier.
      return retrieveToken(audience, tokenType);
    } catch (Exception e) {
      // If token is unavailable, throw IOException.
      throw new IOException(e);
    }
  }

  private String retrieveToken(string tokenType, string audience) {
    // Retrieve a subject token of the requested type for the requested audience.
  }
}
CustomTokenSupplier tokenSupplier = new CustomTokenSupplier();
IdentityPoolCredentials identityPoolCredentials =
    IdentityPoolCredentials.newBuilder()
        .setSubjectTokenSupplier(tokenSupplier) // Sets the token supplier.
        .setAudience(...) // Sets the GCP audience.
        .setSubjectTokenType(SubjectTokenTypes.JWT) // Sets the subject token type.
        .build();

Where the audience is: //iam.googleapis.com/projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$WORKLOAD_POOL_ID/providers/$PROVIDER_ID

Where the following variables need to be substituted:

The values for audience, service account impersonation URL, and any other builder field can also be found by generating a credential configuration file with the gcloud CLI.

Using a custom supplier with AWS

A custom implementation of AwsSecurityCredentialsSupplier can be provided when initializing AwsCredentials. If provided, the AwsCredentials instance will defer to the supplier to retrieve AWS security credentials to exchange for a GCP access token. The supplier must return valid, unexpired AWS security credentials when called by the GCP credential.

AwsCredentials do not cache the returned AWS security credentials or region, so caching logic should be implemented in the supplier to prevent multiple requests for the same resources.

class CustomAwsSupplier implements AwsSecurityCredentialsSupplier {
  @Override
  AwsSecurityCredentials getAwsSecurityCredentials(ExternalAccountSupplierContext context) throws IOException {
    // Any call to the supplier will pass a context object with the requested
    // audience.
    string audience = context.getAudience();

    try {
      // Return valid, unexpired AWS security credentials for the requested audience.
      // Note that AwsCredentials do not cache the AWS security credentials so
      // any caching logic needs to be implemented in the credentials' supplier.
      return retrieveAwsSecurityCredentials(audience);
    } catch (Exception e) {
      // If credentials are unavailable, throw IOException.
      throw new IOException(e);
    }
  }

  @Override
  String getRegion(ExternalAccountSupplierContext context) throws IOException {
    try {
      // Return a valid AWS region. i.e. "us-east-2".
      // Note that AwsCredentials do not cache the region so
      // any caching logic needs to be implemented in the credentials' supplier.
      return retrieveAwsRegion();
    } catch (Exception e) {
      // If region is unavailable, throw IOException.
      throw new IOException(e);
    }
  }

  private AwsSecurityCredentials retrieveAwsSecurityCredentials(string audience) {
    // Retrieve Aws security credentials for the requested audience.
  }

  private String retrieveAwsRegion() {
    // Retrieve current AWS region.
  }
}
CustomAwsSupplier awsSupplier = new CustomAwsSupplier();
AwsCredentials credentials = AwsCredentials.newBuilder()
    .setSubjectTokenType(SubjectTokenTypes.AWS4) // Sets the subject token type.
    .setAudience(...) // Sets the GCP audience.
    .setAwsSecurityCredentialsSupplier(supplier) // Sets the supplier.
    .build();

Where the audience is: //iam.googleapis.com/projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$WORKLOAD_POOL_ID/providers/$PROVIDER_ID

Where the following variables need to be substituted:

The values for audience, service account impersonation URL, and any other builder field can also be found by generating a credential configuration file with the gcloud CLI.

Configurable Token Lifetime

When creating a credential configuration with workload identity federation using service account impersonation, you can provide an optional argument to configure the service account access token lifetime.

To generate the configuration with configurable token lifetime, run the following command (this example uses an AWS configuration, but the token lifetime can be configured for all workload identity federation providers):

# Generate an AWS configuration file with configurable token lifetime.
gcloud iam workload-identity-pools create-cred-config \
    projects/$PROJECT_NUMBER/locations/global/workloadIdentityPools/$POOL_ID/providers/$AWS_PROVIDER_ID \
    --service-account $SERVICE_ACCOUNT_EMAIL \
    --aws \
    --output-file /path/to/generated/config.json \
    --service-account-token-lifetime-seconds $TOKEN_LIFETIME

Where the following variables need to be substituted:

The service-account-token-lifetime-seconds flag is optional. If not provided, this defaults to one hour. The minimum allowed value is 600 (10 minutes) and the maximum allowed value is 43200 (12 hours). If a lifetime greater than one hour is required, the service account must be added as an allowed value in an Organization Policy that enforces the constraints/iam.allowServiceAccountCredentialLifetimeExtension constraint.

Note that configuring a short lifetime (e.g. 10 minutes) will result in the library initiating the entire token exchange flow every 10 minutes, which will call the 3rd party token provider even if the 3rd party token is not expired.

Workforce Identity Federation

Workforce identity federation lets you use an external identity provider (IdP) to authenticate and authorize a workforce—a group of users, such as employees, partners, and contractors—using IAM, so that the users can access Google Cloud services. Workforce identity federation extends Google Cloud's identity capabilities to support syncless, attribute-based single sign on.

With workforce identity federation, your workforce can access Google Cloud resources using an external identity provider (IdP) that supports OpenID Connect (OIDC) or SAML 2.0 such as Azure Active Directory (Azure AD), Active Directory Federation Services (AD FS), Okta, and others.

Accessing resources using an OIDC or SAML 2.0 identity provider

In order to access Google Cloud resources from an identity provider that supports OpenID Connect (OIDC), the following requirements are needed:

Follow the detailed instructions on how to configure workforce identity federation.

After configuring an OIDC or SAML 2.0 provider, a credential configuration file needs to be generated. The generated credential configuration file contains non-sensitive metadata to instruct the library on how to retrieve external subject tokens and exchange them for GCP access tokens. The configuration file can be generated by using the gcloud CLI.

The Auth library can retrieve external subject tokens from a local file location (file-sourced credentials), from a local server (URL-sourced credentials) or by calling an executable (executable-sourced credentials).

File-sourced credentials For file-sourced credentials, a background process needs to be continuously refreshing the file location with a new subject token prior to expiration. For tokens with one hour lifetimes, the token needs to be updated in the file every hour. The token can be stored directly as plain text or in JSON format.

To generate a file-sourced OIDC configuration, run the following command:

# Generate an OIDC configuration file for file-sourced credentials.
gcloud iam workforce-pools create-cred-config \
    locations/global/workforcePools/$WORKFORCE_POOL_ID/providers/$PROVIDER_ID \
    --subject-token-type=urn:ietf:params:oauth:token-type:id_token \
    --credential-source-file=$PATH_TO_OIDC_ID_TOKEN \
    --workforce-pool-user-project=$WORKFORCE_POOL_USER_PROJECT \
    # Optional arguments for file types. Default is "text":
    # --credential-source-type "json" \
    # Optional argument for the field that contains the OIDC credential.
    # This is required for json.
    # --credential-source-field-name "id_token" \
    --output-file=/path/to/generated/config.json

Where the following variables need to be substituted:

To generate a file-sourced SAML configuration, run the following command:

# Generate a SAML configuration file for file-sourced credentials.
gcloud iam workforce-pools create-cred-config \
    locations/global/workforcePools/$WORKFORCE_POOL_ID/providers/$PROVIDER_ID \
    --credential-source-file=$PATH_TO_SAML_ASSERTION \
    --subject-token-type=urn:ietf:params:oauth:token-type:saml2 \
    --workforce-pool-user-project=$WORKFORCE_POOL_USER_PROJECT \
    --output-file=/path/to/generated/config.json 

Where the following variables need to be substituted:

These commands generate the configuration file in the specified output file.

URL-sourced credentials For URL-sourced credentials, a local server needs to host a GET endpoint to return the OIDC token. The response can be in plain text or JSON. Additional required request headers can also be specified.

To generate a URL-sourced OIDC workforce identity configuration, run the following command:

# Generate an OIDC configuration file for URL-sourced credentials.
gcloud iam workforce-pools create-cred-config \
    locations/global/workforcePools/$WORKFORCE_POOL_ID/providers/$PROVIDER_ID \
    --subject-token-type=urn:ietf:params:oauth:token-type:id_token \
    --credential-source-url=$URL_TO_RETURN_OIDC_ID_TOKEN \
    --credential-source-headers $HEADER_KEY=$HEADER_VALUE \
    --workforce-pool-user-project=$WORKFORCE_POOL_USER_PROJECT \
    --output-file=/path/to/generated/config.json

Where the following variables need to be substituted:

To generate a URL-sourced SAML configuration, run the following command:

# Generate a SAML configuration file for file-sourced credentials.
gcloud iam workforce-pools create-cred-config \
    locations/global/workforcePools/$WORKFORCE_POOL_ID/providers/$PROVIDER_ID \
    --subject-token-type=urn:ietf:params:oauth:token-type:saml2 \
    --credential-source-url=$URL_TO_GET_SAML_ASSERTION \
    --credential-source-headers $HEADER_KEY=$HEADER_VALUE \
    --workforce-pool-user-project=$WORKFORCE_POOL_USER_PROJECT \
    --output-file=/path/to/generated/config.json 

These commands generate the configuration file in the specified output file.

Where the following variables need to be substituted:

Using external account authorized user workforce credentials

External account authorized user credentials allow you to sign in with a web browser to an external identity provider account via the gcloud CLI and create a configuration for the auth library to use.

To generate an external account authorized user workforce identity configuration, run the following command:

gcloud auth application-default login --login-config=$LOGIN_CONFIG

Where the following variable needs to be substituted:

This will open a browser flow for you to sign in via the configured third party identity provider and then will store the external account authorized user configuration at the well known ADC location. The auth library will then use the provided refresh token from the configuration to generate and refresh an access token to call Google Cloud services.

Note that the default lifetime of the refresh token is one hour, after which a new configuration will need to be generated from the gcloud CLI. The lifetime can be modified by changing the session duration of the workforce pool, and can be set as high as 12 hours.

Using Executable-sourced workforce credentials with OIDC and SAML

Executable-sourced credentials For executable-sourced credentials, a local executable is used to retrieve the 3rd party token. The executable must handle providing a valid, unexpired OIDC ID token or SAML assertion in JSON format to stdout.

To use executable-sourced credentials, the GOOGLE_EXTERNAL_ACCOUNT_ALLOW_EXECUTABLES environment variable must be set to 1.

To generate an executable-sourced workforce identity configuration, run the following command:

# Generate a configuration file for executable-sourced credentials.
gcloud iam workforce-pools create-cred-config \
    locations/global/workforcePools/$WORKFORCE_POOL_ID/providers/$PROVIDER_ID \
    --subject-token-type=$SUBJECT_TOKEN_TYPE \
    # The absolute path for the program, including arguments.
    # e.g. --executable-command="/path/to/command --foo=bar"
    --executable-command=$EXECUTABLE_COMMAND \
    # Optional argument for the executable timeout. Defaults to 30s.
    # --executable-timeout-millis=$EXECUTABLE_TIMEOUT \
    # Optional argument for the absolute path to the executable output file.
    # See below on how this argument impacts the library behaviour.
    # --executable-output-file=$EXECUTABLE_OUTPUT_FILE \
    --workforce-pool-user-project=$WORKFORCE_POOL_USER_PROJECT \
    --output-file /path/to/generated/config.json

Where the following variables need to be substituted:

The --executable-timeout-millis flag is optional. This is the duration for which the auth library will wait for the executable to finish, in milliseconds. Defaults to 30 seconds when not provided. The maximum allowed value is 2 minutes. The minimum is 5 seconds.

The --executable-output-file flag is optional. If provided, the file path must point to the 3rd party credential response generated by the executable. This is useful for caching the credentials. By specifying this path, the Auth libraries will first check for its existence before running the executable. By caching the executable JSON response to this file, it improves performance as it avoids the need to run the executable until the cached credentials in the output file are expired. The executable must handle writing to this file - the auth libraries will only attempt to read from this location. The format of contents in the file should match the JSON format expected by the executable shown below.

To retrieve the 3rd party token, the library will call the executable using the command specified. The executable's output must adhere to the response format specified below. It must output the response to stdout.

Refer to the using executable-sourced credentials with Workload Identity Federation above for the executable response specification.

Using a custom supplier for workforce credentials with OIDC and SAML

A custom implementation of IdentityPoolSubjectTokenSupplier can be used while building IdentityPoolCredentials to supply a subject token which can be exchanged for a GCP access token. The supplier must return a valid, unexpired subject token when called by the GCP credential.

IdentityPoolCredentials do not cache the returned token, so caching logic should be implemented in the token supplier to prevent multiple requests for the same subject token.

import java.io.IOException;

public class CustomTokenSupplier implements IdentityPoolSubjectTokenSupplier {

  @Override
  public String getSubjectToken(ExternalAccountSupplierContext context) throws IOException {
    // Any call to supplier will pass a context object with the requested
    // audience and subject token type.
    string audience = context.getAudience();
    string tokenType = context.getSubjectTokenType();

    try {
      // Return a valid, unexpired token for the requested audience and token type.
      // Note that the IdentityPoolCredential does not cache the subject token so
      // any caching logic needs to be implemented in the token supplier.
      return retrieveToken(audience, tokenType);
    } catch (Exception e) {
      // If token is unavailable, throw IOException.
      throw new IOException(e);
    }
  }

  private String retrieveToken(string tokenType, string audience) {
    // Retrieve a subject token of the requested type for the requested audience.
  }
}
CustomTokenSupplier tokenSupplier = new CustomTokenSupplier();
IdentityPoolCredentials identityPoolCredentials =
    IdentityPoolCredentials.newBuilder()
        .setSubjectTokenSupplier(tokenSupplier) // Sets the token supplier.
        .setAudience(...) // Sets the GCP audience.
        .setSubjectTokenType(SubjectTokenTypes.JWT) // Sets the subject token type.
        .setWorkforcePoolUserProject(...) // Sets the workforce pool user project.
        .build();

Where the audience is: //iam.googleapis.com/locations/global/workforcePools/$WORKFORCE_POOL_ID/providers/$PROVIDER_ID

Where the following variables need to be substituted:

and the workforce pool user project is the project number associated with the workforce pools user project.

The values for audience, service account impersonation URL, and any other builder field can also be found by generating a credential configuration file with the gcloud CLI.

Security considerations

The following security practices are highly recommended:

Given the complexity of using executable-sourced credentials, it is recommended to use the existing supported mechanisms (file-sourced/URL-sourced) for providing 3rd party credentials unless they do not meet your specific requirements.

You can now use the Auth library to call Google Cloud resources from an OIDC or SAML provider.

Using External Identities

External identities can be used with Application Default Credentials. In order to use external identities with Application Default Credentials, you need to generate the JSON credentials configuration file for your external identity as described above. Once generated, store the path to this file in theGOOGLE_APPLICATION_CREDENTIALS environment variable.

export GOOGLE_APPLICATION_CREDENTIALS=/path/to/config.json

The library can now choose the right type of client and initialize credentials from the context provided in the configuration file.

GoogleCredentials googleCredentials = GoogleCredentials.getApplicationDefault();

String projectId = "your-project-id";
String url = "https://storage.googleapis.com/storage/v1/b?project=" + projectId;

HttpCredentialsAdapter credentialsAdapter = new HttpCredentialsAdapter(googleCredentials);
HttpRequestFactory requestFactory = new NetHttpTransport().createRequestFactory(credentialsAdapter);
HttpRequest request = requestFactory.buildGetRequest(new GenericUrl(url));

JsonObjectParser parser = new JsonObjectParser(GsonFactory.getDefaultInstance());
request.setParser(parser);

HttpResponse response = request.execute();
System.out.println(response.parseAsString());

You can also explicitly initialize external account clients using the generated configuration file.

ExternalAccountCredentials credentials = 
    ExternalAccountCredentials.fromStream(new FileInputStream("/path/to/credentials.json"));
Security Considerations

Note that this library does not perform any validation on the token_url, token_info_url, or service_account_impersonation_url fields of the credential configuration. It is not recommended to use a credential configuration that you did not generate with the gcloud CLI unless you verify that the URL fields point to a googleapis.com domain.

Downscoping with Credential Access Boundaries

Downscoping with Credential Access Boundaries enables the ability to downscope, or restrict, the Identity and Access Management (IAM) permissions that a short-lived credential can use for Cloud Storage.

The DownscopedCredentials class can be used to produce a downscoped access token from a CredentialAccessBoundary and a source credential. The Credential Access Boundary specifies which resources the newly created credential can access, as well as an upper bound on the permissions that are available on each resource. Using downscoped credentials ensures tokens in flight always have the least privileges (Principle of Least Privilege).

The snippet below shows how to initialize a CredentialAccessBoundary with one AccessBoundaryRule which specifies that the downscoped token will have readonly access to objects starting with "customer-a" in bucket "bucket-123":

// Create the AccessBoundaryRule.
String availableResource = "//storage.googleapis.com/projects/_/buckets/bucket-123";
String availablePermission = "inRole:roles/storage.objectViewer";
String expression =  "resource.name.startsWith('projects/_/buckets/bucket-123/objects/customer-a')";

CredentialAccessBoundary.AccessBoundaryRule rule =
    CredentialAccessBoundary.AccessBoundaryRule.newBuilder()
        .setAvailableResource(availableResource)
        .addAvailablePermission(availablePermission)
        .setAvailabilityCondition(
        CredentialAccessBoundary.AccessBoundaryRule.AvailabilityCondition.newBuilder().setExpression(expression).build())
        .build();

// Create the CredentialAccessBoundary with the rule.
CredentialAccessBoundary credentialAccessBoundary = 
        CredentialAccessBoundary.newBuilder().addRule(rule).build();

The common pattern of usage is to have a token broker with elevated access generate these downscoped credentials from higher access source credentials and pass the downscoped short-lived access tokens to a token consumer via some secure authenticated channel for limited access to Google Cloud Storage resources.

Using the CredentialAccessBoundary created above in the Token Broker:

// Retrieve the source credentials from ADC.
GoogleCredentials sourceCredentials = GoogleCredentials.getApplicationDefault()
        .createScoped("https://www.googleapis.com/auth/cloud-platform");

// Initialize the DownscopedCredentials class.
DownscopedCredentials downscopedCredentials =
    DownscopedCredentials.newBuilder()
        .setSourceCredential(credentials)
        .setCredentialAccessBoundary(credentialAccessBoundary)
        .build();

// Retrieve the downscoped access token.
// This will need to be passed to the Token Consumer.
AccessToken downscopedAccessToken = downscopedCredentials.refreshAccessToken();

A token broker can be set up on a server in a private network. Various workloads (token consumers) in the same network will send authenticated requests to that broker for downscoped tokens to access or modify specific google cloud storage buckets.

The broker will instantiate downscoped credentials instances that can be used to generate short lived downscoped access tokens which will be passed to the token consumer.

Putting it all together:

// Retrieve the source credentials from ADC.
GoogleCredentials sourceCredentials = GoogleCredentials.getApplicationDefault()
        .createScoped("https://www.googleapis.com/auth/cloud-platform");

// Create an Access Boundary Rule which will restrict the downscoped token to having readonly
// access to objects starting with "customer-a" in bucket "bucket-123".
String availableResource = "//storage.googleapis.com/projects/_/buckets/bucket-123";
String availablePermission = "inRole:roles/storage.objectViewer";
String expression =  "resource.name.startsWith('projects/_/buckets/bucket-123/objects/customer-a')";
        
CredentialAccessBoundary.AccessBoundaryRule rule =
    CredentialAccessBoundary.AccessBoundaryRule.newBuilder()
        .setAvailableResource(availableResource)
        .addAvailablePermission(availablePermission)
        .setAvailabilityCondition(
            new AvailabilityCondition(expression, /* title= */ null, /* description= */ null))
        .build();

// Initialize the DownscopedCredentials class.
DownscopedCredentials downscopedCredentials =
    DownscopedCredentials.newBuilder()
        .setSourceCredential(credentials)
        .setCredentialAccessBoundary(CredentialAccessBoundary.newBuilder().addRule(rule).build())
        .build();

// Retrieve the downscoped access token.
// This will need to be passed to the Token Consumer.
AccessToken downscopedAccessToken = downscopedCredentials.refreshAccessToken();

These downscoped access tokens can be used by the Token Consumer via OAuth2Credentials or OAuth2CredentialsWithRefresh. This credential can then be used to initialize a storage client instance to access Google Cloud Storage resources with restricted access.

// You can pass an `OAuth2RefreshHandler` to `OAuth2CredentialsWithRefresh` which will allow the
// library to seamlessly handle downscoped token refreshes on expiration.
OAuth2CredentialsWithRefresh.OAuth2RefreshHandler handler = 
        new OAuth2CredentialsWithRefresh.OAuth2RefreshHandler() {
    @Override
    public AccessToken refreshAccessToken() {
      // Add the logic here that retrieves the token from your Token Broker.
      return accessToken;
    }
};

// Downscoped token retrieved from token broker.
AccessToken downscopedToken = handler.refreshAccessToken();

// Build the OAuth2CredentialsWithRefresh from the downscoped token and pass a refresh handler 
// to handle token expiration. Passing the original downscoped token or the expiry here is optional,
// as the refresh_handler will generate the downscoped token on demand.
OAuth2CredentialsWithRefresh credentials =
    OAuth2CredentialsWithRefresh.newBuilder()
        .setAccessToken(downscopedToken)
        .setRefreshHandler(handler)
        .build();

// Use the credentials with the Cloud Storage SDK.
StorageOptions options = StorageOptions.newBuilder().setCredentials(credentials).build();
Storage storage = options.getService();

// Call GCS APIs.
// Since we passed the downscoped credential, we will have have limited readonly access to objects
// starting with "customer-a" in bucket "bucket-123".
storage.get(...)

Note: Only Cloud Storage supports Credential Access Boundaries. Other Google Cloud services do not support this feature.

Configuring a Proxy

For HTTP clients, a basic proxy can be configured by using http.proxyHost and related system properties as documented by Java Networking and Proxies.

For a more custom proxy (e.g. for an authenticated proxy), provide a custom HttpTransportFactory to GoogleCredentials:

import com.google.api.client.http.HttpTransport;
import com.google.api.client.http.apache.v2.ApacheHttpTransport;
import com.google.auth.http.HttpTransportFactory;
import com.google.auth.oauth2.GoogleCredentials;
import org.apache.http.HttpHost;
import org.apache.http.auth.AuthScope;
import org.apache.http.auth.UsernamePasswordCredentials;
import org.apache.http.client.CredentialsProvider;
import org.apache.http.client.HttpClient;
import org.apache.http.conn.routing.HttpRoutePlanner;
import org.apache.http.impl.client.BasicCredentialsProvider;
import org.apache.http.impl.client.ProxyAuthenticationStrategy;
import org.apache.http.impl.conn.DefaultProxyRoutePlanner;

import java.io.IOException;

public class ProxyExample {
  public GoogleCredentials getCredentials() throws IOException {
    HttpTransportFactory httpTransportFactory = getHttpTransportFactory(
        "some-host", 8080, "some-username", "some-password"
    );

    return GoogleCredentials.getApplicationDefault(httpTransportFactory);
  }

  public HttpTransportFactory getHttpTransportFactory(String proxyHost, int proxyPort, String proxyUsername, String proxyPassword) {
    HttpHost proxyHostDetails = new HttpHost(proxyHost, proxyPort);
    HttpRoutePlanner httpRoutePlanner = new DefaultProxyRoutePlanner(proxyHostDetails);

    CredentialsProvider credentialsProvider = new BasicCredentialsProvider();
    credentialsProvider.setCredentials(
        new AuthScope(proxyHostDetails.getHostName(), proxyHostDetails.getPort()),
        new UsernamePasswordCredentials(proxyUsername, proxyPassword)
    );

    HttpClient httpClient = ApacheHttpTransport.newDefaultHttpClientBuilder()
        .setRoutePlanner(httpRoutePlanner)
        .setProxyAuthenticationStrategy(ProxyAuthenticationStrategy.INSTANCE)
        .setDefaultCredentialsProvider(credentialsProvider)
        .build();

    final HttpTransport httpTransport = new ApacheHttpTransport(httpClient);
    return new HttpTransportFactory() {
      @Override
      public HttpTransport create() {
        return httpTransport;
      }
    };
  }
}

The above example requires com.google.http-client:google-http-client-apache-v2.

Using Credentials with google-http-client

Credentials provided by com.google.auth:google-auth-library-oauth2-http can be used with Google's HTTP-based clients. We provide a HttpCredentialsAdapter which can be used as an HttpRequestInitializer, the last argument for their builders.

import com.google.api.client.http.HttpRequestInitializer;
import com.google.api.services.bigquery.Bigquery;
import com.google.auth.http.HttpCredentialsAdapter;
import com.google.auth.oauth2.GoogleCredentials;

GoogleCredentials credentials = GoogleCredentials.getApplicationDefault();
HttpRequestInitializer requestInitializer = new HttpCredentialsAdapter(credentials);

Bigquery bq = new Bigquery.Builder(HTTP_TRANSPORT, JSON_FACTORY, requestInitializer)
    .setApplicationName(APPLICATION_NAME)
    .build();

Verifying JWT Tokens (Beta)

To verify a JWT token, use the TokenVerifier class.

Verifying a Signature

To verify a signature, use the default TokenVerifier:

import com.google.api.client.json.webtoken.JsonWebSignature;
import com.google.auth.oauth2.TokenVerifier;

TokenVerifier tokenVerifier = TokenVerifier.newBuilder().build();
try {
  JsonWebSignature jsonWebSignature = tokenVerifier.verify(tokenString);
  // optionally verify additional claims
  if (!"expected-value".equals(jsonWebSignature.getPayload().get("additional-claim"))) {
    // handle custom verification error
  }
} catch (TokenVerifier.VerificationException e) {
  // invalid token
}

Customizing the TokenVerifier

To customize a TokenVerifier, instantiate it via its builder:

import com.google.api.client.json.webtoken.JsonWebSignature;
import com.google.auth.oauth2.TokenVerifier;

TokenVerifier tokenVerifier = TokenVerifier.newBuilder()
  .setAudience("audience-to-verify")
  .setIssuer("issuer-to-verify")
  .build();
try {
  JsonWebSignature jsonWebSignature = tokenVerifier.verify(tokenString);
  // optionally verify additional claims
  if (!"expected-value".equals(jsonWebSignature.getPayload().get("additional-claim"))) {
    // handle custom verification error
  }
} catch (TokenVerifier.VerificationException e) {
  // invalid token
}

For more options, see the TokenVerifier.Builder documentation.

google-auth-library-credentials

This artifact contains base classes and interfaces for Google credentials:

google-auth-library-appengine

This artifact depends on the App Engine SDK (appengine-api-1.0-sdk) and should be used only by applications running on App Engine environments that use urlfetch. The AppEngineCredentials class allows you to authorize your App Engine application given an instance of AppIdentityService.

Usage:

import com.google.appengine.api.appidentity.AppIdentityService;
import com.google.appengine.api.appidentity.AppIdentityServiceFactory;
import com.google.auth.Credentials;
import com.google.auth.appengine.AppEngineCredentials;

AppIdentityService appIdentityService = AppIdentityServiceFactory.getAppIdentityService();

Credentials credentials =
    AppEngineCredentials.newBuilder()
        .setScopes(...)
        .setAppIdentityService(appIdentityService)
        .build();

Important: com.google.auth.appengine.AppEngineCredentials is a separate class from com.google.auth.oauth2.AppEngineCredentials.

CI Status

Java VersionStatus
Java 8Kokoro CI
Java 8 OSXKokoro CI
Java 8 WindowsKokoro CI
Java 11Kokoro CI

Contributing

Contributions to this library are always welcome and highly encouraged.

See CONTRIBUTING documentation for more information on how to get started.

Please note that this project is released with a Contributor Code of Conduct. By participating in this project you agree to abide by its terms. See Code of Conduct for more information.

Running the Tests

To run the tests you will need:

$ mvn test

License

BSD 3-Clause - See LICENSE for more information.