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Copies of this document may be made for your own use and for distribution to others, provided that you do not charge any fee for such copies and further provided that each copy contains this Copyright Notice, whether distributed in print or electronically. |
Spring Cloud Vault Config provides client-side support for externalized configuration in a distributed system. With HashiCorp’s Vault you have a central place to manage external secret properties for applications across all environments. Vault can manage static and dynamic secrets such as username/password for remote applications/resources and provide credentials for external services such as MySQL, PostgreSQL, Apache Cassandra, MongoDB, Consul, AWS and more.
Quick Start
Prerequisites
To get started with Vault and this guide you need a *NIX-like operating systems that provides:
-
wget
,openssl
andunzip
-
at least Java 8 and a properly configured
JAVA_HOME
environment variable
This guide explains Vault setup from a Spring Cloud Vault perspective for integration testing. You can find a getting started guide directly on the Vault project site: https://learn.hashicorp.com/vault |
Install Vault
$ wget https://releases.hashicorp.com/vault/${vault_version}/vault_${vault_version}_${platform}.zip
$ unzip vault_${vault_version}_${platform}.zip
These steps can be achieved by downloading and running install_vault.sh .
|
Create SSL certificates for Vault
Next, you’r required to generate a set of certificates:
-
Root CA
-
Vault Certificate (decrypted key
work/ca/private/localhost.decrypted.key.pem
and certificatework/ca/certs/localhost.cert.pem
)
Make sure to import the Root Certificate into a Java-compliant truststore.
The easiest way to achieve this is by using OpenSSL.
create_certificates.sh creates certificates in work/ca and a JKS truststore work/keystore.jks .
If you want to run Spring Cloud Vault using this quickstart guide you need to configure the truststore the spring.cloud.vault.ssl.trust-store property to file:work/keystore.jks .
|
Start Vault server
Next create a config file along the lines of:
backend "inmem" {
}
listener "tcp" {
address = "0.0.0.0:8200"
tls_cert_file = "work/ca/certs/localhost.cert.pem"
tls_key_file = "work/ca/private/localhost.decrypted.key.pem"
}
disable_mlock = true
You can find an example config file at vault.conf .
|
$ vault server -config=vault.conf
Vault is started listening on 0.0.0.0:8200
using the inmem
storage and https
.
Vault is sealed and not initialized when starting up.
If you want to run tests, leave Vault uninitialized.
The tests will initialize Vault and create a root token 00000000-0000-0000-0000-000000000000 .
|
If you want to use Vault for your application or give it a try then you need to initialize it first.
$ export VAULT_ADDR="https://localhost:8200"
$ export VAULT_SKIP_VERIFY=true # Don't do this for production
$ vault init
You should see something like:
Key 1: 7149c6a2e16b8833f6eb1e76df03e47f6113a3288b3093faf5033d44f0e70fe701
Key 2: 901c534c7988c18c20435a85213c683bdcf0efcd82e38e2893779f152978c18c02
Key 3: 03ff3948575b1165a20c20ee7c3e6edf04f4cdbe0e82dbff5be49c63f98bc03a03
Key 4: 216ae5cc3ddaf93ceb8e1d15bb9fc3176653f5b738f5f3d1ee00cd7dccbe926e04
Key 5: b2898fc8130929d569c1677ee69dc5f3be57d7c4b494a6062693ce0b1c4d93d805
Initial Root Token: 19aefa97-cccc-bbbb-aaaa-225940e63d76
Vault initialized with 5 keys and a key threshold of 3. Please
securely distribute the above keys. When the Vault is re-sealed,
restarted, or stopped, you must provide at least 3 of these keys
to unseal it again.
Vault does not store the master key. Without at least 3 keys,
your Vault will remain permanently sealed.
Vault will initialize and return a set of unsealing keys and the root token.
Pick 3 keys and unseal Vault.
Store the Vault token in the VAULT_TOKEN
environment variable.
$ vault unseal (Key 1)
$ vault unseal (Key 2)
$ vault unseal (Key 3)
$ export VAULT_TOKEN=(Root token)
# Required to run Spring Cloud Vault tests after manual initialization
$ vault token-create -id="00000000-0000-0000-0000-000000000000" -policy="root"
Spring Cloud Vault accesses different resources. By default, the secret backend is enabled which accesses secret config settings via JSON endpoints.
The HTTP service has resources in the form:
/secret/{application}/{profile} /secret/{application} /secret/{defaultContext}/{profile} /secret/{defaultContext}
where the "application" is injected as the spring.application.name
in the
SpringApplication
(i.e. what is normally "application" in a regular Spring Boot app), "profile" is an active profile (or comma-separated list of properties).
Properties retrieved from Vault will be used "as-is" without further prefixing of the property names.
Client Side Usage
To use these features in an application, just build it as a Spring Boot application that depends on spring-cloud-vault-config
(e.g. see the test cases).
Example Maven configuration:
<parent>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-starter-parent</artifactId>
<version>2.0.0.RELEASE</version>
<relativePath /> <!-- lookup parent from repository -->
</parent>
<dependencies>
<dependency>
<groupId>org.springframework.cloud</groupId>
<artifactId>spring-cloud-starter-vault-config</artifactId>
<version>2.2.8.BUILD-SNAPSHOT</version>
</dependency>
<dependency>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-starter-test</artifactId>
<scope>test</scope>
</dependency>
</dependencies>
<build>
<plugins>
<plugin>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-maven-plugin</artifactId>
</plugin>
</plugins>
</build>
<!-- repositories also needed for snapshots and milestones -->
Then you can create a standard Spring Boot application, like this simple HTTP server:
@SpringBootApplication
@RestController
public class Application {
@RequestMapping("/")
public String home() {
return "Hello World!";
}
public static void main(String[] args) {
SpringApplication.run(Application.class, args);
}
}
When it runs it will pick up the external configuration from the default local Vault server on port 8200
if it is running.
To modify the startup behavior you can change the location of the Vault server using bootstrap.properties
(like application.properties
but for the bootstrap phase of an application context), e.g.
spring.cloud.vault:
host: localhost
port: 8200
scheme: https
uri: https://localhost:8200
connection-timeout: 5000
read-timeout: 15000
config:
order: -10
-
host
sets the hostname of the Vault host. The host name will be used for SSL certificate validation -
port
sets the Vault port -
scheme
setting the scheme tohttp
will use plain HTTP. Supported schemes arehttp
andhttps
. -
uri
configure the Vault endpoint with an URI. Takes precedence over host/port/scheme configuration -
connection-timeout
sets the connection timeout in milliseconds -
read-timeout
sets the read timeout in milliseconds -
config.order
sets the order for the property source
Enabling further integrations requires additional dependencies and configuration. Depending on how you have set up Vault you might need additional configuration like SSL and authentication.
If the application imports the spring-boot-starter-actuator
project, the status of the vault server will be available via the /health
endpoint.
The vault health indicator can be enabled or disabled through the property management.health.vault.enabled
(default to true
).
Authentication
Vault requires an authentication mechanism to authorize client requests.
Spring Cloud Vault supports multiple authentication mechanisms to authenticate applications with Vault.
For a quickstart, use the root token printed by the Vault initialization.
spring.cloud.vault:
token: 19aefa97-cccc-bbbb-aaaa-225940e63d76
Consider carefully your security requirements. Static token authentication is fine if you want quickly get started with Vault, but a static token is not protected any further. Any disclosure to unintended parties allows Vault use with the associated token roles. |
Authentication methods
Different organizations have different requirements for security and authentication. Vault reflects that need by shipping multiple authentication methods. Spring Cloud Vault supports token and AppId authentication.
Token authentication
Tokens are the core method for authentication within Vault. Token authentication requires a static token to be provided using the Bootstrap Application Context.
Token authentication is the default authentication method. If a token is disclosed an unintended party gains access to Vault and can access secrets for the intended client. |
spring.cloud.vault:
authentication: TOKEN
token: 00000000-0000-0000-0000-000000000000
-
authentication
setting this value toTOKEN
selects the Token authentication method -
token
sets the static token to use
See also: Vault Documentation: Tokens
Vault Agent authentication
Vault ships a sidecar utility with Vault Agent since version 0.11.0. Vault Agent implements the functionality of Spring Vault’s SessionManager
with its Auto-Auth feature.
Applications can reuse cached session credentials by relying on Vault Agent running on localhost
.
Spring Vault can send requests without the
X-Vault-Token
header.
Disable Spring Vault’s authentication infrastructure to disable client authentication and session management.
spring.cloud.vault:
authentication: NONE
-
authentication
setting this value toNONE
disablesClientAuthentication
andSessionManager
.
See also: Vault Documentation: Agent
AppId authentication
Vault supports AppId
authentication that consists of two hard to guess tokens.
The AppId defaults to spring.application.name
that is statically configured.
The second token is the UserId which is a part determined by the application, usually related to the runtime environment.
IP address, Mac address or a Docker container name are good examples.
Spring Cloud Vault Config supports IP address, Mac address and static UserId’s (e.g. supplied via System properties).
The IP and Mac address are represented as Hex-encoded SHA256 hash.
IP address-based UserId’s use the local host’s IP address.
spring.cloud.vault:
authentication: APPID
app-id:
user-id: IP_ADDRESS
-
authentication
setting this value toAPPID
selects the AppId authentication method -
app-id-path
sets the path of the AppId mount to use -
user-id
sets the UserId method. Possible values areIP_ADDRESS
,MAC_ADDRESS
or a class name implementing a customAppIdUserIdMechanism
The corresponding command to generate the IP address UserId from a command line is:
$ echo -n 192.168.99.1 | sha256sum
Including the line break of echo leads to a different hash value so make sure to include the -n flag.
|
Mac address-based UserId’s obtain their network device from the localhost-bound device.
The configuration also allows specifying a network-interface
hint to pick the right device.
The value of
network-interface
is optional and can be either an interface name or interface index (0-based).
spring.cloud.vault:
authentication: APPID
app-id:
user-id: MAC_ADDRESS
network-interface: eth0
-
network-interface
sets network interface to obtain the physical address
The corresponding command to generate the IP address UserId from a command line is:
$ echo -n 0AFEDE1234AC | sha256sum
The Mac address is specified uppercase and without colons.
Including the line break of echo leads to a different hash value so make sure to include the -n flag.
|
Custom UserId
The UserId generation is an open mechanism.
You can set
spring.cloud.vault.app-id.user-id
to any string and the configured value will be used as static UserId.
A more advanced approach lets you set spring.cloud.vault.app-id.user-id
to a classname.
This class must be on your classpath and must implement the org.springframework.cloud.vault.AppIdUserIdMechanism
interface and the createUserId
method.
Spring Cloud Vault will obtain the UserId by calling createUserId
each time it authenticates using AppId to obtain a token.
spring.cloud.vault:
authentication: APPID
app-id:
user-id: com.examlple.MyUserIdMechanism
public class MyUserIdMechanism implements AppIdUserIdMechanism {
@Override
public String createUserId() {
String userId = ...
return userId;
}
}
AppRole authentication
AppRole is intended for machine authentication, like the deprecated (since Vault 0.6.1) AppId authentication. AppRole authentication consists of two hard to guess (secret) tokens: RoleId and SecretId.
Spring Vault supports various AppRole scenarios (push/pull mode and wrapped).
RoleId and optionally SecretId must be provided by configuration, Spring Vault will not look up these or create a custom SecretId.
spring.cloud.vault:
authentication: APPROLE
app-role:
role-id: bde2076b-cccb-3cf0-d57e-bca7b1e83a52
The following scenarios are supported along the required configuration details:
Method |
RoleId |
SecretId |
RoleName |
Token |
Provided RoleId/SecretId |
Provided |
Provided |
||
Provided RoleId without SecretId |
Provided |
|||
Provided RoleId, Pull SecretId |
Provided |
Provided |
Provided |
Provided |
Pull RoleId, provided SecretId |
Provided |
Provided |
Provided |
|
Full Pull Mode |
Provided |
Provided |
||
Wrapped |
Provided |
|||
Wrapped RoleId, provided SecretId |
Provided |
Provided |
||
Provided RoleId, wrapped SecretId |
Provided |
Provided |
RoleId |
SecretId |
Supported |
Provided |
Provided |
✅ |
Provided |
Pull |
✅ |
Provided |
Wrapped |
✅ |
Provided |
Absent |
✅ |
Pull |
Provided |
✅ |
Pull |
Pull |
✅ |
Pull |
Wrapped |
❌ |
Pull |
Absent |
❌ |
Wrapped |
Provided |
✅ |
Wrapped |
Pull |
❌ |
Wrapped |
Wrapped |
✅ |
Wrapped |
Absent |
❌ |
You can use still all combinations of push/pull/wrapped modes by providing a configured AppRoleAuthentication bean within the bootstrap context.
Spring Cloud Vault cannot derive all possible AppRole combinations from the configuration properties.
|
AppRole authentication is limited to simple pull mode using reactive infrastructure.
Full pull mode is not yet supported.
Using Spring Cloud Vault with the Spring WebFlux stack enables Vault’s reactive auto-configuration which can be disabled by setting spring.cloud.vault.reactive.enabled=false .
|
spring.cloud.vault:
authentication: APPROLE
app-role:
role-id: bde2076b-cccb-3cf0-d57e-bca7b1e83a52
secret-id: 1696536f-1976-73b1-b241-0b4213908d39
role: my-role
app-role-path: approle
-
role-id
sets the RoleId. -
secret-id
sets the SecretId. SecretId can be omitted if AppRole is configured without requiring SecretId (Seebind_secret_id
). -
role
: sets the AppRole name for pull mode. -
app-role-path
sets the path of the approle authentication mount to use.
AWS-EC2 authentication
The aws-ec2 auth backend provides a secure introduction mechanism for AWS EC2 instances, allowing automated retrieval of a Vault token. Unlike most Vault authentication backends, this backend does not require first-deploying, or provisioning security-sensitive credentials (tokens, username/password, client certificates, etc.). Instead, it treats AWS as a Trusted Third Party and uses the cryptographically signed dynamic metadata information that uniquely represents each EC2 instance.
spring.cloud.vault:
authentication: AWS_EC2
AWS-EC2 authentication enables nonce by default to follow the Trust On First Use (TOFU) principle. Any unintended party that gains access to the PKCS#7 identity metadata can authenticate against Vault.
During the first login, Spring Cloud Vault generates a nonce that is stored in the auth backend aside the instance Id. Re-authentication requires the same nonce to be sent. Any other party does not have the nonce and can raise an alert in Vault for further investigation.
The nonce is kept in memory and is lost during application restart.
You can configure a static nonce with spring.cloud.vault.aws-ec2.nonce
.
AWS-EC2 authentication roles are optional and default to the AMI.
You can configure the authentication role by setting the
spring.cloud.vault.aws-ec2.role
property.
spring.cloud.vault:
authentication: AWS_EC2
aws-ec2:
role: application-server
spring.cloud.vault:
authentication: AWS_EC2
aws-ec2:
role: application-server
aws-ec2-path: aws-ec2
identity-document: http://...
nonce: my-static-nonce
-
authentication
setting this value toAWS_EC2
selects the AWS EC2 authentication method -
role
sets the name of the role against which the login is being attempted. -
aws-ec2-path
sets the path of the AWS EC2 mount to use -
identity-document
sets URL of the PKCS#7 AWS EC2 identity document -
nonce
used for AWS-EC2 authentication. An empty nonce defaults to nonce generation
AWS-IAM authentication
The aws backend provides a secure authentication mechanism for AWS IAM roles, allowing the automatic authentication with vault based on the current IAM role of the running application. Unlike most Vault authentication backends, this backend does not require first-deploying, or provisioning security-sensitive credentials (tokens, username/password, client certificates, etc.). Instead, it treats AWS as a Trusted Third Party and uses the 4 pieces of information signed by the caller with their IAM credentials to verify that the caller is indeed using that IAM role.
The current IAM role the application is running in is automatically calculated. If you are running your application on AWS ECS then the application will use the IAM role assigned to the ECS task of the running container. If you are running your application naked on top of an EC2 instance then the IAM role used will be the one assigned to the EC2 instance.
When using the AWS-IAM authentication you must create a role in Vault and assign it to your IAM role.
An empty role
defaults to the friendly name the current IAM role.
spring.cloud.vault:
authentication: AWS_IAM
spring.cloud.vault:
authentication: AWS_IAM
aws-iam:
role: my-dev-role
aws-path: aws
server-name: some.server.name
endpoint-uri: https://sts.eu-central-1.amazonaws.com
-
role
sets the name of the role against which the login is being attempted. This should be bound to your IAM role. If one is not supplied then the friendly name of the current IAM user will be used as the vault role. -
aws-path
sets the path of the AWS mount to use -
server-name
sets the value to use for theX-Vault-AWS-IAM-Server-ID
header preventing certain types of replay attacks. -
endpoint-uri
sets the value to use for the AWS STS API used for theiam_request_url
parameter.
AWS-IAM requires the AWS Java SDK dependency (com.amazonaws:aws-java-sdk-core
) as the authentication implementation uses AWS SDK types for credentials and request signing.
Azure MSI authentication
The azure auth backend provides a secure introduction mechanism for Azure VM instances, allowing automated retrieval of a Vault token. Unlike most Vault authentication backends, this backend does not require first-deploying, or provisioning security-sensitive credentials (tokens, username/password, client certificates, etc.). Instead, it treats Azure as a Trusted Third Party and uses the managed service identity and instance metadata information that can be bound to a VM instance.
spring.cloud.vault:
authentication: AZURE_MSI
azure-msi:
role: my-dev-role
spring.cloud.vault:
authentication: AZURE_MSI
azure-msi:
role: my-dev-role
azure-path: azure
-
role
sets the name of the role against which the login is being attempted. -
azure-path
sets the path of the Azure mount to use
Azure MSI authentication fetches environmental details about the virtual machine (subscription Id, resource group, VM name) from the instance metadata service.
TLS certificate authentication
The cert
auth backend allows authentication using SSL/TLS client certificates that are either signed by a CA or self-signed.
To enable cert
authentication you need to:
-
Use SSL, see Vault Client SSL configuration
-
Configure a Java
Keystore
that contains the client certificate and the private key -
Set the
spring.cloud.vault.authentication
toCERT
spring.cloud.vault:
authentication: CERT
ssl:
key-store: classpath:keystore.jks
key-store-password: changeit
cert-auth-path: cert
Cubbyhole authentication
Cubbyhole authentication uses Vault primitives to provide a secured authentication workflow.
Cubbyhole authentication uses tokens as primary login method.
An ephemeral token is used to obtain a second, login VaultToken from Vault’s Cubbyhole secret backend.
The login token is usually longer-lived and used to interact with Vault.
The login token will be retrieved from a wrapped response stored at /cubbyhole/response
.
Creating a wrapped token
Response Wrapping for token creation requires Vault 0.6.0 or higher. |
$ vault token-create -wrap-ttl="10m"
Key Value
--- -----
wrapping_token: 397ccb93-ff6c-b17b-9389-380b01ca2645
wrapping_token_ttl: 0h10m0s
wrapping_token_creation_time: 2016-09-18 20:29:48.652957077 +0200 CEST
wrapped_accessor: 46b6aebb-187f-932a-26d7-4f3d86a68319
spring.cloud.vault:
authentication: CUBBYHOLE
token: 397ccb93-ff6c-b17b-9389-380b01ca2645
See also:
GCP-GCE authentication
The gcp auth backend allows Vault login by using existing GCP (Google Cloud Platform) IAM and GCE credentials.
GCP GCE (Google Compute Engine) authentication creates a signature in the form of a JSON Web Token (JWT) for a service account. A JWT for a Compute Engine instance is obtained from the GCE metadata service using Instance identification. This API creates a JSON Web Token that can be used to confirm the instance identity.
Unlike most Vault authentication backends, this backend does not require first-deploying, or provisioning security-sensitive credentials (tokens, username/password, client certificates, etc.). Instead, it treats GCP as a Trusted Third Party and uses the cryptographically signed dynamic metadata information that uniquely represents each GCP service account.
spring.cloud.vault:
authentication: GCP_GCE
gcp-gce:
role: my-dev-role
spring.cloud.vault:
authentication: GCP_GCE
gcp-gce:
gcp-path: gcp
role: my-dev-role
service-account: [email protected]
-
role
sets the name of the role against which the login is being attempted. -
gcp-path
sets the path of the GCP mount to use -
service-account
allows overriding the service account Id to a specific value. Defaults to thedefault
service account.
See also:
GCP-IAM authentication
The gcp auth backend allows Vault login by using existing GCP (Google Cloud Platform) IAM and GCE credentials.
GCP IAM authentication creates a signature in the form of a JSON Web Token (JWT) for a service account.
A JWT for a service account is obtained by calling GCP IAM’s projects.serviceAccounts.signJwt
API. The caller authenticates against GCP IAM and proves thereby its identity.
This Vault backend treats GCP as a Trusted Third Party.
IAM credentials can be obtained from either the runtime environment , specifically the GOOGLE_APPLICATION_CREDENTIALS
environment variable, the Google Compute metadata service, or supplied externally as e.g. JSON or base64 encoded.
JSON is the preferred form as it carries the project id and service account identifier required for calling projects.serviceAccounts.signJwt
.
spring.cloud.vault:
authentication: GCP_IAM
gcp-iam:
role: my-dev-role
spring.cloud.vault:
authentication: GCP_IAM
gcp-iam:
credentials:
location: classpath:credentials.json
encoded-key: e+KApn0=
gcp-path: gcp
jwt-validity: 15m
project-id: my-project-id
role: my-dev-role
service-account-id: [email protected]
-
role
sets the name of the role against which the login is being attempted. -
credentials.location
path to the credentials resource that contains Google credentials in JSON format. -
credentials.encoded-key
the base64 encoded contents of an OAuth2 account private key in the JSON format. -
gcp-path
sets the path of the GCP mount to use -
jwt-validity
configures the JWT token validity. Defaults to 15 minutes. -
project-id
allows overriding the project Id to a specific value. Defaults to the project Id from the obtained credential. -
service-account
allows overriding the service account Id to a specific value. Defaults to the service account from the obtained credential.
GCP IAM authentication requires the Google Cloud Java SDK dependency (com.google.apis:google-api-services-iam
and com.google.auth:google-auth-library-oauth2-http
) as the authentication implementation uses Google APIs for credentials and JWT signing.
Google credentials require an OAuth 2 token maintaining the token lifecycle.
All API is synchronous therefore, GcpIamAuthentication does not support AuthenticationSteps which is required for reactive usage.
|
See also:
Kubernetes authentication
Kubernetes authentication mechanism (since Vault 0.8.3) allows to authenticate with Vault using a Kubernetes Service Account Token. The authentication is role based and the role is bound to a service account name and a namespace.
A file containing a JWT token for a pod’s service account is automatically mounted at /var/run/secrets/kubernetes.io/serviceaccount/token
.
spring.cloud.vault:
authentication: KUBERNETES
kubernetes:
role: my-dev-role
kubernetes-path: kubernetes
service-account-token-file: /var/run/secrets/kubernetes.io/serviceaccount/token
-
role
sets the Role. -
kubernetes-path
sets the path of the Kubernetes mount to use. -
service-account-token-file
sets the location of the file containing the Kubernetes Service Account Token. Defaults to/var/run/secrets/kubernetes.io/serviceaccount/token
.
See also:
Pivotal CloudFoundry authentication
The pcf auth backend provides a secure introduction mechanism for applications running within Pivotal’s CloudFoundry instances allowing automated retrieval of a Vault token. Unlike most Vault authentication backends, this backend does not require first-deploying, or provisioning security-sensitive credentials (tokens, username/password, client certificates, etc.) as identity provisioning is handled by PCF itself. Instead, it treats PCF as a Trusted Third Party and uses the managed instance identity.
spring.cloud.vault:
authentication: PCF
pcf:
role: my-dev-role
spring.cloud.vault:
authentication: PCF
pcf:
role: my-dev-role
pcf-path: path
instance-certificate: /etc/cf-instance-credentials/instance.crt
instance-key: /etc/cf-instance-credentials/instance.key
-
role
sets the name of the role against which the login is being attempted. -
pcf-path
sets the path of the PCF mount to use. -
instance-certificate
sets the path to the PCF instance identity certificate. Defaults to${CF_INSTANCE_CERT}
env variable. -
instance-key
sets the path to the PCF instance identity key. Defaults to${CF_INSTANCE_KEY}
env variable.
PCF authentication requires BouncyCastle (bcpkix-jdk15on) to be on the classpath for RSA PSS signing. |
Secret Backends
Generic Backend
This backend is deprecated in favor of the Key-Value backend and will be removed with the next major version. |
Spring Cloud Vault supports at the basic level the key-value secret backend.
The key-value secret backend allows storage of arbitrary values as key-value store.
A single context can store one or many key-value tuples.
Contexts can be organized hierarchically.
Spring Cloud Vault allows using the Application name and a default context name (application
) in combination with active profiles.
/secret/{application}/{profile} /secret/{application} /secret/{default-context}/{profile} /secret/{default-context}
The application name is determined by the properties:
-
spring.cloud.vault.generic.application-name
-
spring.cloud.vault.application-name
-
spring.application.name
Secrets can be obtained from other contexts within the key-value backend by adding their paths to the application name, separated by commas.
For example, given the application name usefulapp,mysql1,projectx/aws
, each of these folders will be used:
-
/secret/usefulapp
-
/secret/mysql1
-
/secret/projectx/aws
Spring Cloud Vault adds all active profiles to the list of possible context paths. No active profiles will skip accessing contexts with a profile name.
Properties are exposed like they are stored (i.e. without additional prefixes).
spring.cloud.vault:
generic:
enabled: true
backend: secret
profile-separator: '/'
default-context: application
application-name: my-app
-
enabled
setting this value tofalse
disables the secret backend config usage -
backend
sets the path of the secret mount to use -
default-context
sets the context name used by all applications -
application-name
overrides the application name for use in the key-value backend -
profile-separator
separates the profile name from the context in property sources with profiles
Key-Value Backend
Spring Cloud Vault supports the Key-Value secret backend.
The key-value backend allows storage of arbitrary values as key-value store.
A single context can store one or many key-value tuples.
Contexts can be organized hierarchically.
Spring Cloud Vault determines itself whether a secret is using versioning.
Spring Cloud Vault allows using the Application name and a default context name (application
) in combination with active profiles.
/secret/{application}/{profile} /secret/{application} /secret/{default-context}/{profile} /secret/{default-context}
The application name is determined by the properties:
-
spring.cloud.vault.kv.application-name
-
spring.cloud.vault.application-name
-
spring.application.name
Secrets can be obtained from other contexts within the key-value backend by adding their paths to the application name, separated by commas.
For example, given the application name usefulapp,mysql1,projectx/aws
, each of these folders will be used:
-
/secret/usefulapp
-
/secret/mysql1
-
/secret/projectx/aws
Spring Cloud Vault adds all active profiles to the list of possible context paths. No active profiles will skip accessing contexts with a profile name.
Properties are exposed like they are stored (i.e. without additional prefixes).
Spring Cloud Vault adds the data/ context between the mount path and the actual context path.
|
spring.cloud.vault:
kv:
enabled: true
backend: secret
profile-separator: '/'
default-context: application
application-name: my-app
-
enabled
setting this value tofalse
disables the secret backend config usage -
backend
sets the path of the secret mount to use -
default-context
sets the context name used by all applications -
application-name
overrides the application name for use in the key-value backend -
profile-separator
separates the profile name from the context in property sources with profiles
The key-value secret backend can be operated in versioned (v2) and non-versioned (v1) modes. |
See also:
Consul
Spring Cloud Vault can obtain credentials for HashiCorp Consul.
The Consul integration requires the spring-cloud-vault-config-consul
dependency.
<dependencies>
<dependency>
<groupId>org.springframework.cloud</groupId>
<artifactId>spring-cloud-vault-config-consul</artifactId>
<version>2.2.8.BUILD-SNAPSHOT</version>
</dependency>
</dependencies>
The integration can be enabled by setting
spring.cloud.vault.consul.enabled=true
(default false
) and providing the role name with spring.cloud.vault.consul.role=…
.
The obtained token is stored in spring.cloud.consul.token
so using Spring Cloud Consul can pick up the generated credentials without further configuration.
You can configure the property name by setting spring.cloud.vault.consul.token-property
.
spring.cloud.vault:
consul:
enabled: true
role: readonly
backend: consul
token-property: spring.cloud.consul.token
-
enabled
setting this value totrue
enables the Consul backend config usage -
role
sets the role name of the Consul role definition -
backend
sets the path of the Consul mount to use -
token-property
sets the property name in which the Consul ACL token is stored
RabbitMQ
Spring Cloud Vault can obtain credentials for RabbitMQ.
The RabbitMQ integration requires the spring-cloud-vault-config-rabbitmq
dependency.
<dependencies>
<dependency>
<groupId>org.springframework.cloud</groupId>
<artifactId>spring-cloud-vault-config-rabbitmq</artifactId>
<version>2.2.8.BUILD-SNAPSHOT</version>
</dependency>
</dependencies>
The integration can be enabled by setting
spring.cloud.vault.rabbitmq.enabled=true
(default false
) and providing the role name with spring.cloud.vault.rabbitmq.role=…
.
Username and password are stored in spring.rabbitmq.username
and spring.rabbitmq.password
so using Spring Boot will pick up the generated credentials without further configuration.
You can configure the property names by setting spring.cloud.vault.rabbitmq.username-property
and
spring.cloud.vault.rabbitmq.password-property
.
spring.cloud.vault:
rabbitmq:
enabled: true
role: readonly
backend: rabbitmq
username-property: spring.rabbitmq.username
password-property: spring.rabbitmq.password
-
enabled
setting this value totrue
enables the RabbitMQ backend config usage -
role
sets the role name of the RabbitMQ role definition -
backend
sets the path of the RabbitMQ mount to use -
username-property
sets the property name in which the RabbitMQ username is stored -
password-property
sets the property name in which the RabbitMQ password is stored
AWS
Spring Cloud Vault can obtain credentials for AWS.
The AWS integration requires the spring-cloud-vault-config-aws
dependency.
<dependencies>
<dependency>
<groupId>org.springframework.cloud</groupId>
<artifactId>spring-cloud-vault-config-aws</artifactId>
<version>2.2.8.BUILD-SNAPSHOT</version>
</dependency>
</dependencies>
The integration can be enabled by setting
spring.cloud.vault.aws=true
(default false
) and providing the role name with spring.cloud.vault.aws.role=…
.
The access key and secret key are stored in cloud.aws.credentials.accessKey
and cloud.aws.credentials.secretKey
so using Spring Cloud AWS will pick up the generated credentials without further configuration.
You can configure the property names by setting spring.cloud.vault.aws.access-key-property
and
spring.cloud.vault.aws.secret-key-property
.
spring.cloud.vault:
aws:
enabled: true
role: readonly
backend: aws
access-key-property: cloud.aws.credentials.accessKey
secret-key-property: cloud.aws.credentials.secretKey
-
enabled
setting this value totrue
enables the AWS backend config usage -
role
sets the role name of the AWS role definition -
backend
sets the path of the AWS mount to use -
access-key-property
sets the property name in which the AWS access key is stored -
secret-key-property
sets the property name in which the AWS secret key is stored
Database backends
Vault supports several database secret backends to generate database credentials dynamically based on configured roles. This means services that need to access a database no longer need to configure credentials: they can request them from Vault, and use Vault’s leasing mechanism to more easily roll keys.
Spring Cloud Vault integrates with these backends:
Using a database secret backend requires to enable the backend in the configuration and the spring-cloud-vault-config-databases
dependency.
Vault ships since 0.7.1 with a dedicated database
secret backend that allows database integration via plugins.
You can use that specific backend by using the generic database backend.
Make sure to specify the appropriate backend path, e.g. spring.cloud.vault.mysql.role.backend=database
.
<dependencies>
<dependency>
<groupId>org.springframework.cloud</groupId>
<artifactId>spring-cloud-vault-config-databases</artifactId>
<version>2.2.8.BUILD-SNAPSHOT</version>
</dependency>
</dependencies>
Enabling multiple JDBC-compliant databases will generate credentials and store them by default in the same property keys hence property names for JDBC secrets need to be configured separately. |
Database
Spring Cloud Vault can obtain credentials for any database listed at
https://www.vaultproject.io/api/secret/databases/index.html.
The integration can be enabled by setting
spring.cloud.vault.database.enabled=true
(default false
) and providing the role name with spring.cloud.vault.database.role=…
.
While the database backend is a generic one, spring.cloud.vault.database
specifically targets JDBC databases.
Username and password are stored in spring.datasource.username
and spring.datasource.password
so using Spring Boot will pick up the generated credentials for your DataSource
without further configuration.
You can configure the property names by setting
spring.cloud.vault.database.username-property
and
spring.cloud.vault.database.password-property
.
spring.cloud.vault:
database:
enabled: true
role: readonly
backend: database
username-property: spring.datasource.username
password-property: spring.datasource.password
-
enabled
setting this value totrue
enables the Database backend config usage -
role
sets the role name of the Database role definition -
backend
sets the path of the Database mount to use -
username-property
sets the property name in which the Database username is stored -
password-property
sets the property name in which the Database password is stored
Spring Cloud Vault does not support getting new credentials and configuring your DataSource with them when the maximum lease time has been reached.
That is, if max_ttl of the Database role in Vault is set to 24h that means that 24 hours after your application has started it can no longer authenticate with the database.
|
Apache Cassandra
The cassandra backend has been deprecated in Vault 0.7.1 and it is recommended to use the database backend and mount it as cassandra .
|
Spring Cloud Vault can obtain credentials for Apache Cassandra.
The integration can be enabled by setting
spring.cloud.vault.cassandra.enabled=true
(default false
) and providing the role name with spring.cloud.vault.cassandra.role=…
.
Username and password are stored in spring.data.cassandra.username
and spring.data.cassandra.password
so using Spring Boot will pick up the generated credentials without further configuration.
You can configure the property names by setting
spring.cloud.vault.cassandra.username-property
and
spring.cloud.vault.cassandra.password-property
.
spring.cloud.vault:
cassandra:
enabled: true
role: readonly
backend: cassandra
username-property: spring.data.cassandra.username
password-property: spring.data.cassandra.password
-
enabled
setting this value totrue
enables the Cassandra backend config usage -
role
sets the role name of the Cassandra role definition -
backend
sets the path of the Cassandra mount to use -
username-property
sets the property name in which the Cassandra username is stored -
password-property
sets the property name in which the Cassandra password is stored
MongoDB
The mongodb backend has been deprecated in Vault 0.7.1 and it is recommended to use the database backend and mount it as mongodb .
|
Spring Cloud Vault can obtain credentials for MongoDB.
The integration can be enabled by setting
spring.cloud.vault.mongodb.enabled=true
(default false
) and providing the role name with spring.cloud.vault.mongodb.role=…
.
Username and password are stored in spring.data.mongodb.username
and spring.data.mongodb.password
so using Spring Boot will pick up the generated credentials without further configuration.
You can configure the property names by setting
spring.cloud.vault.mongodb.username-property
and
spring.cloud.vault.mongodb.password-property
.
spring.cloud.vault:
mongodb:
enabled: true
role: readonly
backend: mongodb
username-property: spring.data.mongodb.username
password-property: spring.data.mongodb.password
-
enabled
setting this value totrue
enables the MongodB backend config usage -
role
sets the role name of the MongoDB role definition -
backend
sets the path of the MongoDB mount to use -
username-property
sets the property name in which the MongoDB username is stored -
password-property
sets the property name in which the MongoDB password is stored
MySQL
The mysql backend has been deprecated in Vault 0.7.1 and it is recommended to use the database backend and mount it as mysql .
Configuration for spring.cloud.vault.mysql will be removed in a future version.
|
Spring Cloud Vault can obtain credentials for MySQL.
The integration can be enabled by setting
spring.cloud.vault.mysql.enabled=true
(default false
) and providing the role name with spring.cloud.vault.mysql.role=…
.
Username and password are stored in spring.datasource.username
and spring.datasource.password
so using Spring Boot will pick up the generated credentials without further configuration.
You can configure the property names by setting
spring.cloud.vault.mysql.username-property
and
spring.cloud.vault.mysql.password-property
.
spring.cloud.vault:
mysql:
enabled: true
role: readonly
backend: mysql
username-property: spring.datasource.username
password-property: spring.datasource.password
-
enabled
setting this value totrue
enables the MySQL backend config usage -
role
sets the role name of the MySQL role definition -
backend
sets the path of the MySQL mount to use -
username-property
sets the property name in which the MySQL username is stored -
password-property
sets the property name in which the MySQL password is stored
PostgreSQL
The postgresql backend has been deprecated in Vault 0.7.1 and it is recommended to use the database backend and mount it as postgresql .
Configuration for spring.cloud.vault.postgresql will be removed in a future version.
|
Spring Cloud Vault can obtain credentials for PostgreSQL.
The integration can be enabled by setting
spring.cloud.vault.postgresql.enabled=true
(default false
) and providing the role name with spring.cloud.vault.postgresql.role=…
.
Username and password are stored in spring.datasource.username
and spring.datasource.password
so using Spring Boot will pick up the generated credentials without further configuration.
You can configure the property names by setting
spring.cloud.vault.postgresql.username-property
and
spring.cloud.vault.postgresql.password-property
.
spring.cloud.vault:
postgresql:
enabled: true
role: readonly
backend: postgresql
username-property: spring.datasource.username
password-property: spring.datasource.password
-
enabled
setting this value totrue
enables the PostgreSQL backend config usage -
role
sets the role name of the PostgreSQL role definition -
backend
sets the path of the PostgreSQL mount to use -
username-property
sets the property name in which the PostgreSQL username is stored -
password-property
sets the property name in which the PostgreSQL password is stored
Configure PropertySourceLocator
behavior
Spring Cloud Vault uses property-based configuration to create PropertySource
s for key-value and discovered secret backends.
Discovered backends provide VaultSecretBackendDescriptor
beans to describe the configuration state to use secret backend as PropertySource
.
A SecretBackendMetadataFactory
is required to create a SecretBackendMetadata
object which contains path, name and property transformation configuration.
SecretBackendMetadata
is used to back a particular PropertySource
.
You can register an arbitrary number of beans implementing VaultConfigurer
for customization.
Default key-value and discovered backend registration is disabled if Spring Cloud Vault discovers at least one VaultConfigurer
bean.
You can however enable default registration with
SecretBackendConfigurer.registerDefaultKeyValueSecretBackends()
and SecretBackendConfigurer.registerDefaultDiscoveredSecretBackends()
.
public class CustomizationBean implements VaultConfigurer {
@Override
public void addSecretBackends(SecretBackendConfigurer configurer) {
configurer.add("secret/my-application");
configurer.registerDefaultKeyValueSecretBackends(false);
configurer.registerDefaultDiscoveredSecretBackends(true);
}
}
All customization is required to happen in the bootstrap context.
Add your configuration classes to META-INF/spring.factories at org.springframework.cloud.bootstrap.BootstrapConfiguration
in your application.
|
Service Registry Configuration
You can use a DiscoveryClient
(such as from Spring Cloud Consul) to locate a Vault server by setting spring.cloud.vault.discovery.enabled=true (default false
).
The net result of that is that your apps need a bootstrap.yml (or an environment variable) with the appropriate discovery configuration.
The benefit is that the Vault can change its co-ordinates, as long as the discovery service is a fixed point.
The default service id is vault
but you can change that on the client with
spring.cloud.vault.discovery.serviceId
.
The discovery client implementations all support some kind of metadata map (e.g. for Eureka we have eureka.instance.metadataMap).
Some additional properties of the service may need to be configured in its service registration metadata so that clients can connect correctly.
Service registries that do not provide details about transport layer security need to provide a scheme
metadata entry to be set either to https
or http
.
If no scheme is configured and the service is not exposed as secure service, then configuration defaults to spring.cloud.vault.scheme
which is https
when it’s not set.
spring.cloud.vault.discovery:
enabled: true
service-id: my-vault-service
Vault Client Fail Fast
In some cases, it may be desirable to fail startup of a service if it cannot connect to the Vault Server.
If this is the desired behavior, set the bootstrap configuration property
spring.cloud.vault.fail-fast=true
and the client will halt with an Exception.
spring.cloud.vault:
fail-fast: true
Vault Enterprise Namespace Support
Vault Enterprise allows using namespaces to isolate multiple Vaults on a single Vault server.
Configuring a namespace by setting
spring.cloud.vault.namespace=…
enables the namespace header
X-Vault-Namespace
on every outgoing HTTP request when using the Vault
RestTemplate
or WebClient
.
Please note that this feature is not supported by Vault Community edition and has no effect on Vault operations.
spring.cloud.vault:
namespace: my-namespace
See also: Vault Enterprise: Namespaces
Vault Client SSL configuration
SSL can be configured declaratively by setting various properties.
You can set either javax.net.ssl.trustStore
to configure JVM-wide SSL settings or spring.cloud.vault.ssl.trust-store
to set SSL settings only for Spring Cloud Vault Config.
spring.cloud.vault:
ssl:
trust-store: classpath:keystore.jks
trust-store-password: changeit
-
trust-store
sets the resource for the trust-store. SSL-secured Vault communication will validate the Vault SSL certificate with the specified trust-store. -
trust-store-password
sets the trust-store password
Please note that configuring spring.cloud.vault.ssl.*
can be only applied when either Apache Http Components or the OkHttp client is on your class-path.
Lease lifecycle management (renewal and revocation)
With every secret, Vault creates a lease: metadata containing information such as a time duration, renewability, and more.
Vault promises that the data will be valid for the given duration, or Time To Live (TTL). Once the lease is expired, Vault can revoke the data, and the consumer of the secret can no longer be certain that it is valid.
Spring Cloud Vault maintains a lease lifecycle beyond the creation of login tokens and secrets. That said, login tokens and secrets associated with a lease are scheduled for renewal just before the lease expires until terminal expiry. Application shutdown revokes obtained login tokens and renewable leases.
Secret service and database backends (such as MongoDB or MySQL) usually generate a renewable lease so generated credentials will be disabled on application shutdown.
Static tokens are not renewed or revoked. |
Lease renewal and revocation is enabled by default and can be disabled by setting spring.cloud.vault.config.lifecycle.enabled
to false
.
This is not recommended as leases can expire and Spring Cloud Vault cannot longer access Vault or services using generated credentials and valid credentials remain active after application shutdown.
spring.cloud.vault:
config.lifecycle:
enabled: true
min-renewal: 10s
expiry-threshold: 1m
lease-endpoints: Legacy
-
enabled
controls whether leases associated with secrets are considered to be renewed and expired secrets are rotated. Enabled by default. -
min-renewal
sets the duration that is at least required before renewing a lease. This setting prevents renewals from happening too often. -
expiry-threshold
sets the expiry threshold. A lease is renewed the configured period of time before it expires. -
lease-endpoints
sets the endpoints for renew and revoke. Legacy for vault versions before 0.8 and SysLeases for later.