<#import "/templates/guide.adoc" as tmpl> <#import "/templates/kc.adoc" as kc> <#import "/templates/options.adoc" as opts> <#import "/templates/links.adoc" as links> <@tmpl.guide title="Using a reverse proxy" summary="Learn how to configure {project_name} together with a reverse proxy, api gateway, or load balancer." includedOptions="proxy proxy-* hostname-path hostname-url http-relative-path"> Distributed environments frequently require the use of a reverse proxy. {project_name} offers several options to securely integrate with such environments. == Configure the reverse proxy headers {project_name} will parse the reverse proxy headers based on the `proxy-headers` option which accepts several values: * By default if the option is not specified, no reverse proxy headers are parsed. * `forwarded` enables parsing of the `Forwarded` header as per https://www.rfc-editor.org/rfc/rfc7239.html[RFC7239]. * `xforwarded` enables parsing of non-standard `X-Forwarded-*` headers, such as `X-Forwarded-For`, `X-Forwarded-Proto`, `X-Forwarded-Host`, and `X-Forwarded-Port`. For example: <@kc.start parameters="--proxy-headers forwarded"/> WARNING: If either `forwarded` or `xforwarded` is selected, make sure your reverse proxy properly sets and overwrites the `Forwarded` or `X-Forwarded-*` headers respectively. To set these headers, consult the documentation for your reverse proxy. Misconfiguration will leave {project_name} exposed to security vulnerabilities. Take extra precautions to ensure that the client address is properly set by your reverse proxy via the `Forwarded` or `X-Forwarded-For` headers. If this header is incorrectly configured, rogue clients can set this header and trick {project_name} into thinking the client is connected from a different IP address than the actual address. This precaution can be more critical if you do any deny or allow listing of IP addresses. NOTE: When using the `xforwarded` setting, the `X-Forwarded-Port` takes precedence over any port included in the `X-Forwarded-Host`. NOTE: If the TLS connection is terminated at the reverse proxy (edge termination), enabling HTTP through the ‘http-enabled’ setting is required. == Proxy modes (deprecated) NOTE: The support for setting proxy modes is deprecated and will be removed in a future {project_name} release. Consider configuring accepted reverse proxy headers instead as described in the chapter above. For migration instructions consult the https://www.keycloak.org/docs/latest/upgrading/index.html#deprecated-proxy-option[Upgrading Guide]. For {project_name}, your choice of proxy modes depends on the TLS termination in your environment. The following proxy modes are available: edge:: Enables communication through HTTP between the proxy and {project_name}. This mode is suitable for deployments with a highly secure internal network where the reverse proxy keeps a secure connection (HTTP over TLS) with clients while communicating with {project_name} using HTTP. reencrypt:: Requires communication through HTTPS between the proxy and {project_name}. This mode is suitable for deployments where internal communication between the reverse proxy and {project_name} should also be protected. Different keys and certificates are used on the reverse proxy as well as on {project_name}. passthrough:: The proxy forwards the HTTPS connection to {project_name} without terminating TLS. The secure connections between the server and clients are based on the keys and certificates used by the {project_name} server. When in **edge** or **reencrypt** proxy mode, {project_name} will parse the following headers and expects the reverse proxy to set them: * `Forwarded` as per https://www.rfc-editor.org/rfc/rfc7239.html[RFC7239] * Non-standard `X-Forwarded-*`, such as `X-Forwarded-For`, `X-Forwarded-Proto`, `X-Forwarded-Host`, and `X-Forwarded-Port` === Configure the proxy mode in {project_name} To select the proxy mode, enter this command: <@kc.start parameters="--proxy "/> == Different context-path on reverse proxy {project_name} assumes it is exposed through the reverse proxy under the same context path as {project_name} is configured for. By default {project_name} is exposed through the root (`/`), which means it expects to be exposed through the reverse proxy on `/` as well. You can use a full URL for the `hostname` option in these cases, for example using `--hostname=https://my.keycloak.org/auth` if {project_name} is exposed through the reverse proxy on `/auth`. For more details on exposing {project_name} on different hostname or context-path incl. Administration REST API and Console, see <@links.server id="hostname"/>. Alternatively you can also change the context path of {project_name} itself to match the context path for the reverse proxy using the `http-relative-path` option, which will change the context-path of {project_name} itself to match the context path used by the reverse proxy. == Enable sticky sessions Typical cluster deployment consists of the load balancer (reverse proxy) and 2 or more {project_name} servers on private network. For performance purposes, it may be useful if load balancer forwards all requests related to particular browser session to the same {project_name} backend node. The reason is, that {project_name} is using Infinispan distributed cache under the covers for save data related to current authentication session and user session. The Infinispan distributed caches are configured with two owners by default. That means that particular session is primarily stored on two cluster nodes and the other nodes need to lookup the session remotely if they want to access it. For example if authentication session with ID 123 is saved in the Infinispan cache on node1, and then node2 needs to lookup this session, it needs to send the request to node1 over the network to return the particular session entity. It is beneficial if particular session entity is always available locally, which can be done with the help of sticky sessions. The workflow in the cluster environment with the public frontend load balancer and two backend {project_name} nodes can be like this: * User sends initial request to see the {project_name} login screen * This request is served by the frontend load balancer, which forwards it to some random node (eg. node1). Strictly said, the node doesn't need to be random, but can be chosen according to some other criteria (client IP address etc). It all depends on the implementation and configuration of underlying load balancer (reverse proxy). * {project_name} creates authentication session with random ID (eg. 123) and saves it to the Infinispan cache. * Infinispan distributed cache assigns the primary owner of the session based on the hash of session ID. See Infinispan documentation for more details around this. Let's assume that Infinispan assigned node2 to be the owner of this session. * {project_name} creates the cookie AUTH_SESSION_ID with the format like . . In our example case, it will be 123.node2 . * Response is returned to the user with the {project_name} login screen and the AUTH_SESSION_ID cookie in the browser From this point, it is beneficial if load balancer forwards all the next requests to the node2 as this is the node, who is owner of the authentication session with ID 123 and hence Infinispan can lookup this session locally. After authentication is finished, the authentication session is converted to user session, which will be also saved on node2 because it has same ID 123 . The sticky session is not mandatory for the cluster setup, however it is good for performance for the reasons mentioned above. You need to configure your loadbalancer to sticky over the AUTH_SESSION_ID cookie. How exactly do this is dependent on your loadbalancer. If your proxy supports session affinity without processing cookies from backend nodes, you should set the `spi-sticky-session-encoder-infinispan-should-attach-route` option to `false` in order to avoid attaching the node to cookies and just rely on the reverse proxy capabilities. <@kc.start parameters="--spi-sticky-session-encoder-infinispan-should-attach-route=false"/> By default, the `spi-sticky-session-encoder-infinispan-should-attach-route` option value is `true` so that the node name is attached to cookies to indicate to the reverse proxy the node that subsequent requests should be sent to. == Exposed path recommendations When using a reverse proxy, {project_name} only requires certain paths need to be exposed. The following table shows the recommended paths to expose. [%autowidth] |=== |{project_name} Path|Reverse Proxy Path|Exposed|Reason |/ |- |No |When exposing all paths, admin paths are exposed unnecessarily. |/admin/ | - |No |Exposed admin paths lead to an unnecessary attack vector. |/js/ | - |Yes (see note below) |Access to keycloak.js needed for "internal" clients, e.g. the account console |/realms/ |/realms/ |Yes |This path is needed to work correctly, for example, for OIDC endpoints. |/resources/ |/resources/ |Yes |This path is needed to serve assets correctly. It may be served from a CDN instead of the {project_name} path. |/robots.txt |/robots.txt |Yes |Search engine rules |/metrics |- |No |Exposed metrics lead to an unnecessary attack vector. |/health |- |No |Exposed health checks lead to an unnecessary attack vector. |=== [NOTE] As it's true that the `js` path is needed for internal clients like the account console, it's good practice to use `keycloak.js` from a JavaScript package manager like npm or yarn for your external clients. We assume you run {project_name} on the root path `/` on your reverse proxy/gateway's public API. If not, prefix the path with your desired one. == Enabling client certificate lookup When the proxy is configured as a TLS termination proxy the client certificate information can be forwarded to the server through specific HTTP request headers and then used to authenticate clients. You are able to configure how the server is going to retrieve client certificate information depending on the proxy you are using. The server supports some of the most commons TLS termination proxies such as: [%autowidth] |=== |Proxy|Provider |Apache HTTP Server |apache |HAProxy |haproxy |NGINX |nginx |=== To configure how client certificates are retrieved from the requests you need to: .Enable the corresponding proxy provider <@kc.build parameters="--spi-x509cert-lookup-provider="/> .Configure the HTTP headers <@kc.start parameters="--spi-x509cert-lookup--ssl-client-cert=SSL_CLIENT_CERT --spi-x509cert-lookup--ssl-cert-chain-prefix=CERT_CHAIN --spi-x509cert-lookup--certificate-chain-length=10"/> When configuring the HTTP headers, you need to make sure the values you are using correspond to the name of the headers forwarded by the proxy with the client certificate information. The available options for configuring a provider are: [%autowidth] |=== |Option|Description |ssl-client-cert | The name of the header holding the client certificate |ssl-cert-chain-prefix | The prefix of the headers holding additional certificates in the chain and used to retrieve individual certificates accordingly to the length of the chain. For instance, a value `CERT_CHAIN` will tell the server to load additional certificates from headers `CERT_CHAIN_0` to `CERT_CHAIN_9` if `certificate-chain-length` is set to `10`. |certificate-chain-length | The maximum length of the certificate chain. |trust-proxy-verification | Enable trusting NGINX proxy certificate verification, instead of forwarding the certificate to {project_name} and verifying it in {project_name}. |=== === Configuring the NGINX provider The NGINX SSL/TLS module does not expose the client certificate chain. {project_name}'s NGINX certificate lookup provider rebuilds it by using the {project_name} truststore. If you are using this provider, see <@links.server id="keycloak-truststore"/> for how to configure a {project_name} Truststore.