opensearch-docs-cn/docs/security/configuration/configuration.md

403 lines
16 KiB
Markdown
Raw Normal View History

2021-05-05 13:09:47 -04:00
---
layout: default
title: Backend Configuration
parent: Configuration
grand_parent: Security
nav_order: 2
---
# Backend configuration
One of the first steps to using the security plugin is to decide on an authentication backend, which handles [steps 2-3 of the authentication flow](../concepts/#authentication-flow). The plugin has an internal user database, but many people prefer to use an existing authentication backend, such as an LDAP server, or some combination of the two.
The main configuration file for authentication and authorization backends is `plugins/opensearch_security/securityconfig/config.yml`. It defines how the security plugin retrieves the user credentials, how it verifies these credentials, and how to fetch additional roles from backend systems (optional).
`config.yml` has three main parts:
```yml
opensearch_security:
dynamic:
http:
...
authc:
...
authz:
...
```
For a more complete example, see the [sample file on GitHub](https://github.com/opensearch-project/security/blob/master/securityconfig/config.yml).
## HTTP
The `http` section has the following format:
```yml
anonymous_auth_enabled: <true|false>
xff: # optional section
enabled: <true|false>
internalProxies: <string> # Regex pattern
remoteIpHeader: <string> # Name of the header in which to look. Typically: x-forwarded-for
proxiesHeader: <string>
trustedProxies: <string> # Regex pattern
```
If you disable anonymous authentication, the security plugin won't initialize if you have not provided at least one `authc`.
## Authentication
The `authc` section has the following format:
```yml
<name>:
http_enabled: <true|false>
transport_enabled: <true|false>
order: <integer>
http_authenticator:
...
authentication_backend:
...
```
An entry in the `authc` section is called an *authentication domain*. It specifies where to get the user credentials and against which backend they should be authenticated.
You can use more than one authentication domain. Each authentication domain has a name (for example, `basic_auth_internal`), `enabled` flags, and an `order`. The order makes it possible to chain authentication domains together. The security plugin uses them in the order that you provide. If the user successfully authenticates with one domain, the security plugin skips the remaining domains.
`http_authenticator` specifies which authentication method that you want to use on the HTTP layer.
This is the syntax for defining an authenticator on the HTTP layer:
```yml
http_authenticator:
type: <type>
challenge: <true|false>
config:
...
```
These are the allowed values for `type`:
- `basic`: HTTP basic authentication. No additional configuration is needed.
- `kerberos`: Kerberos authentication. Additional, [Kerberos-specific configuration](#kerberos) is needed.
- `jwt`: JSON web token authentication. Additional, [JWT-specific configuration](#json-web-token) is needed.
- `clientcert`: Authentication through a client TLS certificate. This certificate must be trusted by one of the root CAs in the truststore of your nodes.
After setting an HTTP authenticator, you must specify against which backend system you want to authenticate the user:
```yml
authentication_backend:
type: <type>
config:
...
```
These are the possible values for `type`:
- `noop`: No further authentication against any backend system is performed. Use `noop` if the HTTP authenticator has already authenticated the user completely, as in the case of JWT, Kerberos, or client certificate authentication.
- `internal`: Use the users and roles defined in `internal_users.yml` for authentication.
- `ldap`: Authenticate users against an LDAP server. This setting requires [additional, LDAP-specific configuration settings](../ldap/).
## Authorization
After the user has been authenticated, the security plugin can optionally collect additional roles from backend systems. The authorization configuration has the following format:
```yml
authz:
<name>:
http_enabled: <true|false>
transport_enabled: <true|false>
authorization_backend:
type: <type>
config:
...
```
You can define multiple entries in this section the same way as you can for authentication entries. In this case, execution order is not relevant, so there is no `order` field.
These are the possible values for `type`:
- `noop`: Skip this step altogether.
- `ldap`: Fetch additional roles from an LDAP server. This setting requires [additional, LDAP-specific configuration settings](../ldap/).
## Examples
The default `plugins/opensearch_security/securityconfig/config.yml` that ships with OpenSearch contains many configuration examples. Use these examples as a starting point, and customize them to your needs.
## HTTP basic
To set up HTTP basic authentication, you must enable it in the `http_authenticator` section of the configuration:
```yml
http_authenticator:
type: basic
challenge: true
```
In most cases, you set the `challenge` flag to `true`. The flag defines the behavior of the security plugin if the `Authorization` field in the HTTP header is not set.
If `challenge` is set to `true`, the security plugin sends a response with status `UNAUTHORIZED` (401) back to the client. If the client is accessing the cluster with a browser, this triggers the authentication dialog box, and the user is prompted to enter a user name and password.
If `challenge` is set to `false` and no `Authorization` header field is set, the security plugin does not send a `WWW-Authenticate` response back to the client, and authentication fails. You might want to use this setting if you have another challenge `http_authenticator` in your configured authentication domains. One such scenario is when you plan to use basic authentication and Kerberos together.
## Kerberos
Due to the nature of Kerberos, you must define some settings in `opensearch.yml` and some in `config.yml`.
In `opensearch.yml`, define the following:
```yml
opensearch_security.kerberos.krb5_filepath: '/etc/krb5.conf'
opensearch_security.kerberos.acceptor_keytab_filepath: 'eskeytab.tab'
```
`opensearch_security.kerberos.krb5_filepath` defines the path to your Kerberos configuration file. This file contains various settings regarding your Kerberos installation, for example, the realm names, hostnames, and ports of the Kerberos key distribution center (KDC).
`opensearch_security.kerberos.acceptor_keytab_filepath` defines the path to the keytab file, which contains the principal that the security plugin uses to issue requests against Kerberos.
`opensearch_security.kerberos.acceptor_principal: 'HTTP/localhost'` defines the principal that the security plugin uses to issue requests against Kerberos. This value must be present in the keytab file.
Due to security restrictions, the keytab file must be placed in `config` or a subdirectory, and the path in `opensearch.yml` must be relative, not absolute.
{: .warning }
### Dynamic configuration
A typical Kerberos authentication domain in `config.yml` looks like this:
```yml
authc:
kerberos_auth_domain:
enabled: true
order: 1
http_authenticator:
type: kerberos
challenge: true
config:
krb_debug: false
strip_realm_from_principal: true
authentication_backend:
type: noop
```
Authentication against Kerberos through a browser on an HTTP level is achieved using SPNEGO. Kerberos/SPNEGO implementations vary, depending on your browser and operating system. This is important when deciding if you need to set the `challenge` flag to `true` or `false`.
As with [HTTP Basic Authentication](#http-basic), this flag determines how the security plugin should react when no `Authorization` header is found in the HTTP request or if this header does not equal `negotiate`.
If set to `true`, the security plugin sends a response with status code 401 and a `WWW-Authenticate` header set to `negotiate`. This tells the client (browser) to resend the request with the `Authorization` header set. If set to `false`, the security plugin cannot extract the credentials from the request, and authentication fails. Setting `challenge` to `false` thus makes sense only if the Kerberos credentials are sent in the initial request.
As the name implies, setting `krb_debug` to `true` will output Kerberos-specific debugging messages to `stdout`. Use this setting if you encounter problems with your Kerberos integration.
If you set `strip_realm_from_principal` to `true`, the security plugin strips the realm from the user name.
### Authentication backend
Because Kerberos/SPNEGO authenticates users on an HTTP level, no additional `authentication_backend` is needed. Set this value to `noop`.
## JSON web token
JSON web tokens (JWTs) are JSON-based access tokens that assert one or more claims. They are commonly used to implement single sign-on (SSO) solutions and fall in the category of token-based authentication systems:
1. A user logs in to an authentication server by providing credentials (for example, a user name and password).
1. The authentication server validates the credentials.
1. The authentication server creates an access token and signs it.
1. The authentication server returns the token to the user.
1. The user stores the access token.
1. The user sends the access token alongside every request to the service that it wants to use.
1. The service verifies the token and grants or denies access.
A JSON web token is self-contained in the sense that it carries all necessary information to verify a user within itself. The tokens are base64-encoded, signed JSON objects.
JSON web tokens consist of three parts:
1. Header
1. Payload
1. Signature
### Header
The header contains information about the used signing mechanism, as shown in the following example:
```json
{
"alg": "HS256",
"typ": "JWT"
}
```
In this case, the header states that the message was signed using HMAC-SHA256.
### Payload
The payload of a JSON web token contains the so-called [JWT Claims](http://self-issued.info/docs/draft-ietf-oauth-json-web-token.html#RegisteredClaimName). A claim can be any piece of information about the user that the application that created the token has verified.
The specification defines a set of standard claims with reserved names ("registered claims"). These include, for example, the token issuer, the expiration date, or the creation date.
Public claims, on the other hand, can be created freely by the token issuer. They can contain arbitrary information, such as the user name and the roles of the user.
Example:
```json
{
"iss": "example.com",
"exp": 1300819380,
"name": "John Doe",
"roles": "admin, devops"
}
```
### Signature
The issuer of the token calculates the signature of the token by applying a cryptographic hash function on the base64-encoded header and payload. These three parts are then concatenated using periods to form a complete JSON web token:
```
encoded = base64UrlEncode(header) + "." + base64UrlEncode(payload)
signature = HMACSHA256(encoded, 'secretkey');
jwt = encoded + "." + base64UrlEncode(signature)
```
Example:
```
eyJhbGciOiJIUzI1NiIsInR5cCI6IkpXVCJ9.eyJsb2dnZWRJbkFzIjoiYWRtaW4iLCJpYXQiOjE0MjI3Nzk2Mzh9.gzSraSYS8EXBxLN_oWnFSRgCzcmJmMjLiuyu5CSpyHI
```
### Configure JSON web tokens
If JSON web tokens are the only authentication method that you use, disable the user cache by setting `opensearch_security.cache.ttl_minutes: 0`.
{: .warning }
Set up an authentication domain and choose `jwt` as the HTTP authentication type. Because the tokens already contain all required information to verify the request, `challenge` must be set to `false` and `authentication_backend` to `noop`.
Example:
```yml
jwt_auth_domain:
enabled: true
order: 0
http_authenticator:
type: jwt
challenge: false
config:
signing_key: "base64 encoded key"
jwt_header: "Authorization"
jwt_url_parameter: null
subject_key: null
roles_key: null
authentication_backend:
I type: noop
```
The following table shows the configuration parameters.
Name | Description
:--- | :---
`signing_key` | The signing key to use when verifying the token. If you use a symmetric key algorithm, it is the base64-encoded shared secret. If you use an asymmetric algorithm, it contains the public key.
`jwt_header` | The HTTP header in which the token is transmitted. This typically is the `Authorization` header with the `Bearer` schema: `Authorization: Bearer <token>`. Default is `Authorization`.
`jwt_url_parameter` | If the token is not transmitted in the HTTP header, but as an URL parameter, define the name of this parameter here.
`subject_key` | The key in the JSON payload that stores the user name. If not set, the [subject](https://tools.ietf.org/html/rfc7519#section-4.1.2) registered claim is used.
`roles_key` | The key in the JSON payload that stores the user's roles. The value of this key must be a comma-separated list of roles.
Because JSON web tokens are self-contained and the user is authenticated on the HTTP level, no additional `authentication_backend` is needed. Set this value to `noop`.
### Symmetric key algorithms: HMAC
Hash-based message authentication codes (HMACs) are a group of algorithms that provide a way of signing messages by means of a shared key. The key is shared between the authentication server and the security plugin. It must be configured as a base64-encoded value in the `signing_key` setting:
```yml
jwt_auth_domain:
...
config:
signing_key: "a3M5MjEwamRqOTAxOTJqZDE="
...
```
### Asymmetric key algorithms: RSA and ECDSA
RSA and ECDSA are asymmetric encryption and digital signature algorithms and use a public/private key pair to sign and verify tokens. This means that they use a private key for signing the token, while the security plugin needs to know only the public key to verify it.
Because you cannot issue new tokens with the public key---and because you can make valid assumptions about the creator of the token---RSA and ECDSA are considered more secure than using HMAC.
To use RS256, you need to configure only the (non-base64-encoded) public RSA key as `signing_key` in the JWT configuration:
```yml
jwt_auth_domain:
...
config:
signing_key: |-
-----BEGIN PUBLIC KEY-----
MIGfMA0GCSqGSIb3DQEBAQUAA4GNADCBiQK...
-----END PUBLIC KEY-----
...
```
The security plugin automatically detects the algorithm (RSA/ECDSA), and if necessary you can break the key into multiple lines.
### Bearer authentication for HTTP requests
The most common way of transmitting a JSON web token in an HTTP request is to add it as an HTTP header with the bearer authentication schema:
```
Authorization: Bearer <JWT>
```
The default name of the header is `Authorization`. If required by your authentication server or proxy, you can also use a different HTTP header name using the `jwt_header` configuration key.
As with HTTP basic authentication, you should use HTTPS instead of HTTP when transmitting JSON web tokens in HTTP requests.
### URL parameters for HTTP requests
Although the most common way to transmit JWTs in HTTP requests is to use a header field, the security plugin also supports parameters. Configure the name of the `GET` parameter using the following key:
```yml
config:
signing_key: ...
jwt_url_parameter: "parameter_name"
subject_key: ...
roles_key: ...
```
As with HTTP basic authentication, you should use HTTPS instead of HTTP.
### Validated registered claims
The following registered claims are validated automatically:
* "iat" (Issued At) Claim
* "nbf" (Not Before) Claim
* "exp" (Expiration Time) Claim
### Supported formats and algorithms
The security plugin supports digitally signed, compact JSON web tokens with all standard algorithms:
```
HS256: HMAC using SHA-256
HS384: HMAC using SHA-384
HS512: HMAC using SHA-512
RS256: RSASSA-PKCS-v1_5 using SHA-256
RS384: RSASSA-PKCS-v1_5 using SHA-384
RS512: RSASSA-PKCS-v1_5 using SHA-512
PS256: RSASSA-PSS using SHA-256 and MGF1 with SHA-256
PS384: RSASSA-PSS using SHA-384 and MGF1 with SHA-384
PS512: RSASSA-PSS using SHA-512 and MGF1 with SHA-512
ES256: ECDSA using P-256 and SHA-256
ES384: ECDSA using P-384 and SHA-384
ES512: ECDSA using P-521 and SHA-512
```