Deis (pronounced DAY-iss) Workflow is an open source Platform as a Service (PaaS) that adds a developer-friendly layer to any Kubernetes cluster, making it easy to deploy and manage applications on your own servers.
We welcome your input! If you have feedback, please submit an issue. If you'd like to participate in development, please read the "Development" section below and submit a pull request.
The Deis router handles ingress and routing of HTTP/S traffic bound for the Deis Workflow controller (API) and for your own applications. This component is 100% Kubernetes native and, while it's intended for use with the Deis Workflow PaaS, it's flexible enough to be used standalone inside any Kubernetes cluster.
The Deis project welcomes contributions from all developers. The high level process for development matches many other open source projects. See below for an outline.
- Fork this repository
- Make your changes
- Submit a pull request (PR) to this repository with your changes, and unit tests whenever possible.
- If your PR fixes any issues, make sure you write Fixes #1234 in your PR description (where #1234 is the number of the issue you're closing)
- The Deis core contributors will review your code. After each of them sign off on your code, they'll label your PR with
LGTM1
andLGTM2
(respectively). Once that happens, they'll merge it.
This section documents simple procedures for installing the Deis Router for evaluation or use. Those wishing to contribute to Deis Router development might consider the more developer-oriented instructions in the Hacking Router section.
Deis Router can be installed with or without the rest of the Deis Workflow platform. In either case, begin with a healthy Kubernetes cluster. Kubernetes getting started documentation is available here.
Next, install the Helm Classic package manager, then use the commands below to initialize that tool and load the deis/charts repository.
$ helmc update
$ helmc repo add deis https://github.com/deis/charts
To install the router:
$ helmc fetch deis/<chart>
$ helmc generate -x manifests <chart>
$ helmc install <chart>
Where <chart>
is selected from the options below:
Chart | Description |
---|---|
workflow-rc2 | Install the router along with the rest of the latest stable Deis Workflow release. |
workflow-dev | Install the router from master with the rest of the edge Deis Workflow platform. |
router-dev | Install the router from master with its minimal set of dependencies. |
For next steps, skip ahead to the How it Works and Configuration Guide sections.
The only dependencies for hacking on / contributing to this component are:
git
make
docker
kubectl
, properly configured to manipulate a healthy Kubernetes cluster that you presumably use for development- Your favorite text editor
Although the router is written in Go, you do not need Go or any other development tools installed. Any parts of the developer workflow requiring tools not listed above are delegated to a containerized Go development environment.
The following sections setup, build, deploy, and test the Deis Router. You'll need a configured Docker registry to push changed images to so that they can be deployed to your Kubernetes cluster. You can easily make use of a public registry such as hub.docker.com, provided you have an account. To do so:
$ export DEIS_REGISTRY=registry.hub.docker.com/
$ export IMAGE_PREFIX=your-username
The entire developer workflow for anyone hacking on the router is implemented as a set of make
targets. They are simple and easy to use, and collectively provide a workflow that should feel familiar to anyone who has hacked on Deis v1.x in the past.
To "bootstrap" the development environment:
$ make bootstrap
In router's case, this step carries out some extensive dependency management using glide within the containerized development environment. Because the router leverages the Kubernetes API, which in turn has in excess of one hundred dependencies, this step can take quite some time. Be patient, and allow up to 20 minutes. You generally only ever have to do this once.
$ make build
Make sure to have defined the variable DEIS_REGISTRY
previous to this step, as your image tags will be prefixed according to this.
Built images will be tagged with the sha of the latest git commit. This means that for a new image to have its own unique tag, experimental changes should be committed before building. Do this in a branch. Commits can be squashed later when you are done hacking.
$ make deploy
The deploy target will implicitly build first, then push the built image (which has its own unique tags) to your development registry (i.e. that specified by DEIS_REGISTRY
). A Kubernetes manifest is prepared, referencing the uniquely tagged image, and that manifest is submitted to your Kubernetes cluster. If a router component is already running in your Kubernetes cluster, it will be deleted and replaced with your build.
To see that the router is running, you can look for its pod(s):
$ kubectl get pods --namespace=deis
To deploy some sample routable applications:
$ make examples
This will deploy Nginx and Apache to your Kubernetes cluster as if they were user applications.
To test, first modify your /etc/hosts
such that the following four hostnames are resolvable to the IP of the Kubernetes node that is hosting the router:
- nginx.example.com
- apache.example.com
- httpd.example.com
- unknown.example.com
By requesting the following three URLs from your browser, you should find that one is routed to a pod running Nginx, while the other two are routed to a pod running Apache:
Requesting http://unknown.example.com should result in a 404 from the router since no route exists for that domain name.
The router is implemented as a simple Go program that manages Nginx and Nginx configuration. It regularly queries the Kubernetes API for services labeled with router.deis.io/routable: "true"
. Such services are compared to known services resident in memory. If there are differences, new Nginx configuration is generated and Nginx is reloaded.
Routable services must expose port 80. The target port in underlying pods may be anything, but the service itself must expose port 80. For example:
apiVersion: v1
kind: Service
metadata:
name: foo
labels:
router.deis.io/routable: "true"
namespace: examples
annotations:
router.deis.io/domains: www.foobar.com
spec:
selector:
app: foo
ports:
- port: 80
targetPort: 3000
# ...
When generating configuration, the program reads all annotations of each service prefixed with router.deis.io
. These annotations describe all the configuration options that allow the program to dynamically construct Nginx configuration, including virtual hosts for all the domain names associated with each routable application.
Similarly, the router watches the annotations on its own deployment object to dynamically construct global Nginx configuration.
Router configuration is driven almost entirely by annotations on the router's deployment object and the services of all routable applications-- those labeled with router.deis.io/routable: "true"
.
One exception to this, however, is that in order for the router to discover its own annotations, the router must be configured via environment variable with some awareness of its own namespace. (It cannot query the API for information about itself without knowing this.)
The POD_NAMESPACE
environment variable is required by the router and it should be configured to match the Kubernetes namespace that the router is deployed into. If no value is provided, the router will assume a value of default
.
For example, consider the following Kubernetes manifest. Given a manifest containing the following metadata:
apiVersion: extensions/v1beta1
kind: Deployment
metadata:
name: deis-router
namespace: deis
# ...
The corresponding template must inject a POD_NAMESPACE=deis
environment variable into router containers. The most elegant way to achieve this is by means of the Kubernetes "downward API," as in this snippet from the same manifest:
# ...
spec:
# ...
template:
# ...
spec:
containers:
- name: deis-router
# ...
env:
- name: POD_NAMESPACE
valueFrom:
fieldRef:
fieldPath: metadata.namespace
# ...
Altering the value of the POD_NAMESPACE
environment variable requires the router to be restarted for changes to take effect.
All remaining options are configured through annotations. Any of the following three Kubernetes resources can be configured:
Resource | Notes |
---|---|
|
All of these configuration options are specific to this implementation of the router (as indicated by the inclusion of the token nginx in the annotations' names). Customized and alternative router implementations are possible. Such routers are under no obligation to honor these annotations, as many or all of these may not be applicable in such scenarios. Customized and alternative implementations should document their own configuration options. |
|
These are services labeled with router.deis.io/routable: "true" . In the context of the broader Deis Workflow PaaS, these annotations are written by the Deis Workflow controller component (the API). These annotations, therefore, represent the contract or interface between that component and the router. As such, any customized or alternative router implementations that wishes to remain compatible with deis-controller must honor (or ignore) these annotations, but may not alter their names or redefine their meanings. |
The table below details the configuration options that are available for each of the above.
Note that Kubernetes annotation maps are all of Go type map[string]string
. As such, all configuration values must also be strings. To avoid Kubernetes attempting to populate the map[string]string
with non-string values, all numeric and boolean configuration values should be enclosed in double quotes to help avoid confusion.
Component | Resource Type | Annotation | Default Value | Description |
---|---|---|---|---|
deis-router | deployment | router.deis.io/nginx.workerProcesses | "auto" (number of CPU cores) |
Number of worker processes to start. |
deis-router | deployment | router.deis.io/nginx.maxWorkerConnections | "768" |
Maximum number of simultaneous connections that can be opened by a worker process. |
deis-router | deployment | router.deis.io/nginx.trafficStatusZoneSize | "1m" |
Size of a shared memory zone for storing stats collected by the Nginx VTS module expressed in bytes (no suffix), kilobytes (suffixes k and K ), or megabytes (suffixes m and M ). |
deis-router | deployment | router.deis.io/nginx.defaultTimeout | "1300s" |
Default timeout value expressed in units ms , s , m , h , d , w , M , or y . Should be longer than the front-facing load balancer's idle timeout. |
deis-router | deployment | router.deis.io/nginx.serverNameHashMaxSize | "512" |
nginx server_names_hash_max_size setting expressed in bytes (no suffix), kilobytes (suffixes k and K ), or megabytes (suffixes m and M ). |
deis-router | deployment | router.deis.io/nginx.serverNameHashBucketSize | "64" |
nginx server_names_hash_bucket_size setting expressed in bytes (no suffix), kilobytes (suffixes k and K ), or megabytes (suffixes m and M ). |
deis-router | deployment | router.deis.io/nginx.requestIDs | "false" |
Whether to add X-Request-Id and X-Correlation-Id headers. |
deis-router | deployment | router.deis.io/nginx.gzip.enabled | "true" |
Whether to enable gzip compression. |
deis-router | deployment | router.deis.io/nginx.gzip.compLevel | "5" |
nginx gzip_comp_level setting. |
deis-router | deployment | router.deis.io/nginx.gzip.disable | "msie6" |
nginx gzip_disable setting. |
deis-router | deployment | router.deis.io/nginx.gzip.httpVersion | "1.1" |
nginx gzip_http_version setting. |
deis-router | deployment | router.deis.io/nginx.gzip.minLength | "256" |
nginx gzip_min_length setting. |
deis-router | deployment | router.deis.io/nginx.gzip.proxied | "any" |
nginx gzip_proxied setting. |
deis-router | deployment | router.deis.io/nginx.gzip.types | "application/atom+xml application/javascript application/json application/rss+xml application/vnd.ms-fontobject application/x-font-ttf application/x-web-app-manifest+json application/xhtml+xml application/xml font/opentype image/svg+xml image/x-icon text/css text/plain text/x-component" |
nginx gzip_types setting. |
deis-router | deployment | router.deis.io/nginx.gzip.vary | "on" |
nginx gzip_vary setting. |
deis-router | deployment | router.deis.io/nginx.bodySize | "1m" |
nginx client_max_body_size setting expressed in bytes (no suffix), kilobytes (suffixes k and K ), or megabytes (suffixes m and M ). |
deis-router | deployment | router.deis.io/nginx.proxyRealIpCidrs | "10.0.0.0/8" |
Comma-delimited list of IP/CIDRs that define trusted addresses that are known to send correct replacement addresses. These map to multiple nginx set_real_ip_from directives. |
deis-router | deployment | router.deis.io/nginx.errorLogLevel | "error" |
Log level used in the nginx error_log setting (valid values are: debug , info , notice , warn , error , crit , alert , and emerg ). |
deis-router | deployment | router.deis.io/nginx.platformDomain | N/A | This defines the router's platform domain. Any domains added to a routable application not containing the . character will be assumed to be subdomains of this platform domain. Thus, for example, a platform domain of example.com coupled with a routable app counting foo among its domains will result in router configuration that routes traffic for foo.example.com to that application. |
deis-router | deployment | router.deis.io/nginx.useProxyProtocol | "false" |
PROXY is a simple protocol supported by nginx, HAProxy, Amazon ELB, and others. It provides a method to obtain information about a request's originating IP address from an external (to Kubernetes) load balancer in front of the router. Enabling this option allows the router to select the originating IP from the HTTP X-Forwarded-For header. |
deis-router | deployment | router.deis.io/nginx.enforceWhitelists | "false" |
Whether to require application-level whitelists that explicitly enumerate allowed clients by IP / CIDR range. With this enabled, each app will drop all requests unless a whitelist has been defined. |
deis-router | deployment | router.deis.io/nginx.defaultWhitelist | N/A | A default (router-wide) whitelist expressed as a comma-delimited list of addresses (using IP or CIDR notation). Application-specific whitelists can either extend or override this default. |
deis-router | deployment | router.deis.io/nginx.whitelistMode | "extend" |
Whether application-specific whitelists should extend or override the router-wide default whitelist (if defined). Valid values are "extend" and "override" . |
deis-router | deployment | router.deis.io/nginx.http2Enabled | "true" |
Whether to enable HTTP2 for apps on the SSL ports. |
deis-router | deployment | router.deis.io/nginx.ssl.enforce | "false" |
Whether to respond with a 301 for all HTTP requests with a permanent redirect to the HTTPS equivalent address. |
deis-router | deployment | router.deis.io/nginx.ssl.protocols | "TLSv1 TLSv1.1 TLSv1.2" |
nginx ssl_protocols setting. |
deis-router | deployment | router.deis.io/nginx.ssl.ciphers | "ECDHE-ECDSA-CHACHA20-POLY1305:ECDHE-RSA-CHACHA20-POLY1305:ECDHE-ECDSA-AES128-GCM-SHA256:ECDHE-RSA-AES128-GCM-SHA256:ECDHE-ECDSA-AES256-GCM-SHA384:ECDHE-RSA-AES256-GCM-SHA384:DHE-RSA-AES128-GCM-SHA256:DHE-RSA-AES256-GCM-SHA384:ECDHE-ECDSA-AES128-SHA256:ECDHE-RSA-AES128-SHA256:ECDHE-ECDSA-AES128-SHA:ECDHE-RSA-AES256-SHA384:ECDHE-RSA-AES128-SHA:ECDHE-ECDSA-AES256-SHA384:ECDHE-ECDSA-AES256-SHA:ECDHE-RSA-AES256-SHA:DHE-RSA-AES128-SHA256:DHE-RSA-AES128-SHA:DHE-RSA-AES256-SHA256:DHE-RSA-AES256-SHA:ECDHE-ECDSA-DES-CBC3-SHA:ECDHE-RSA-DES-CBC3-SHA:EDH-RSA-DES-CBC3-SHA:AES128-GCM-SHA256:AES256-GCM-SHA384:AES128-SHA256:AES256-SHA256:AES128-SHA:AES256-SHA:DES-CBC3-SHA:!DSS" |
nginx ssl_ciphers . The default ciphers are taken from the intermediate compatibility section in the Mozilla Wiki on Security/Server Side TLS. If the value is set to the empty string, OpenSSL's default ciphers are used. In all cases, server side cipher preferences (order matters) are used. |
deis-router | deployment | router.deis.io/nginx.ssl.sessionCache | "" |
nginx ssl_session_cache setting. |
deis-router | deployment | router.deis.io/nginx.ssl.sessionTimeout | "10m" |
nginx ssl_session_timeout expressed in units ms , s , m , h , d , w , M , or y . |
deis-router | deployment | router.deis.io/nginx.ssl.useSessionTickets | "true" |
Whether to use TLS session tickets for session resumption without server-side state. |
deis-router | deployment | router.deis.io/nginx.ssl.bufferSize | "4k" |
nginx ssl_buffer_size setting expressed in bytes (no suffix), kilobytes (suffixes k and K ), or megabytes (suffixes m and M ). |
deis-router | deployment | router.deis.io/nginx.ssl.hsts.enabled | "false" |
Whether to use HTTP Strict Transport Security. |
deis-router | deployment | router.deis.io/nginx.ssl.hsts.maxAge | "10886400" |
Maximum number of seconds user agents should observe HSTS rewrites. |
deis-router | deployment | router.deis.io/nginx.ssl.hsts.includeSubDomains | "false" |
Whether to enforce HSTS for subsequent requests to all subdomains of the original request. |
deis-router | deployment | router.deis.io/nginx.ssl.hsts.preload | "false" |
Whether to allow the domain to be included in the HSTS preload list. |
deis-builder | service | router.deis.io/nginx.connectTimeout | "10s" |
nginx proxy_connect_timeout setting expressed in units ms , s , m , h , d , w , M , or y . |
deis-builder | service | router.deis.io/nginx.tcpTimeout | "1200s" |
nginx proxy_timeout setting expressed in units ms , s , m , h , d , w , M , or y . |
routable application | service | router.deis.io/domains | N/A | Comma-delimited list of domains for which traffic should be routed to the application. These may be fully qualified (e.g. foo.example.com ) or, if not containing any . character, will be considered subdomains of the router's domain, if that is defined. |
routable application | service | router.deis.io/certificates | N/A | Comma delimited list of mappings between domain names (see router.deis.io/domains ) and the certificate to be used for each. The domain name and certificate name must be separated by a colon. See the SSL section below for further details. |
routable application | service | router.deis.io/whitelist | N/A | Comma-delimited list of addresses permitted to access the application (using IP or CIDR notation). These may either extend or override the router-wide default whitelist (if defined). Requests from all other addresses are denied. |
routable application | service | router.deis.io/connectTimeout | "30s" |
nginx proxy_connect_timeout setting expressed in units ms , s , m , h , d , w , M , or y . |
routable application | service | router.deis.io/tcpTimeout | router's defaultTimeout |
nginx proxy_send_timeout and proxy_read_timeout settings expressed in units ms , s , m , h , d , w , M , or y . |
routable application | service | router.deis.io/maintenance | "false" |
Whether the app is under maintenance so that all traffic for this app is redirected to a static maintenance page with an error code of 503 . |
routable application | service | router.deis.io/ssl.enforce | "false" |
Whether to respond with a 301 for all HTTP requests with a permanent redirect to the HTTPS equivalent address. |
apiVersion: extensions/v1beta1
kind: Deployment
metadata:
name: deis-router
namespace: deis
# ...
annotations:
router.deis.io/nginx.platformDomain: example.com
router.deis.io/nginx.useProxyProtocol: "true"
# ...
apiVersion: v1
kind: Service
metadata:
name: deis-builder
namespace: deis
# ...
annotations:
router.deis.io/nginx.connectTimeout: "20000"
router.deis.io/nginx.tcpTimeout: "2400000"
# ...
apiVersion: v1
kind: Service
metadata:
name: foo
labels:
router.deis.io/routable: "true"
namespace: examples
# ...
annotations:
router.deis.io/domains: foo,bar,www.foobar.com
# ...
Router has support for HTTPS with the ability to perform SSL termination using certificates supplied via Kubernetes secrets. Just as router utilizes the Kubernetes API to discover routable services, router also uses the API to discover cert-bearing secrets. This allows the router to dynamically refresh and reload configuration whenever such a certificate is added, updated, or removed. There is never a need to explicitly restart the router.
A certificate may be supplied in the manner described above and can be used to provide a secure virtual host (in addition to the insecure virtual host) for any fully-qualified domain name associated with a routable service.
Here is an example of a Kubernetes secret bearing a certificate for use with a specific fully-qualified domain name. The following criteria must be met:
- Secret name must be for the form
<arbitrary name>-cert
- This must be associated to the domain using the router.deis.io/certificates annotation.
- Must be in the same namespace as the routable service
- Certificate must be supplied as the value of the key
tls.crt
- Certificate private key must be supplied as the value of the key
tls.key
- Both the certificate and private key must be base64 encoded
For example, assuming a routable service exists in the namespace cheery-yardbird
and is configured with www.example.com
among its domains, like so:
apiVersion: v1
kind: Service
metadata:
namespace: cheery-yardbird
annotations:
router.deis.io/domains: cheery-yardbird,www.example.com
router.deis.io/certificates: www.example.com:www-example-com"
# ...
The corresponding cert-bearing secret would appear as follows:
apiVersion: v1
kind: Secret
metadata:
name: www-example-com-cert
namespace: cheery-yardbird
type: Opaque
data:
tls.crt: MT1...uDh==
tls.key: MT1...MRp=
A wildcard certificate may be supplied in a manner similar to that described above and can be used as a platform certificate to provide a secure virtual host (in addition to the insecure virtual host) for every "domain" of a routable service that is not a fully-qualified domain name.
For instance, if a routable service exists having a "domain" frozen-wookie
and the router's platform domain is example.com
, a supplied wildcard certificate for *.example.com
will be used to secure a frozen-wookie.example.com
virtual host. Similarly, if no platform domain is defined, the supplied wildcard certificate will be used to secure a virtual host matching the expression ~^frozen-wookie\.(?<domain>.+)$
. (The latter is almost certainly guaranteed to result in certificate warnings in an end user's browser, so it is advisable to always define the router's platform domain.)
If the same routable service also had a domain www.frozen-wookie.com
, the *.example.com
wildcard certificate plays no role in securing the www.frozen-wookie.com
virtual host.
Here is an example of a Kubernetes secret bearing a wildcard certificate for use by the router. The following criteria must be met:
- Namespace must be the same namespace as the router
- Name must be
deis-router-platform-cert
- Certificate must be supplied as the value of the key
tls.crt
- Certificate private key must be supplied as the value of the key
tls.key
- Both the certificate and private key must be base64 encoded
For example:
apiVersion: v1
kind: Secret
metadata:
name: deis-router-platform-cert
namespace: deis
type: Opaque
data:
tls.crt: LS0...tCg==
tls.key: LS0...LQo=
When combined with a good certificate, the router's default SSL options are sufficient to earn an A grade from Qualys SSL Labs.
Earning an A+ is as easy as simply enabling HTTP Strict Transport Security (see the router.deis.io/nginx.ssl.hsts.enabled
option), but be aware that this will implicitly trigger the router.deis.io/nginx.ssl.enforce
option and cause your applications to permanently use HTTPS for all requests.
Depending on what distribution of Kubernetes you use and where you host it, installation of the router may automatically include an external (to Kubernetes) load balancer or similar mechanism for routing inbound traffic from beyond the cluster into the cluster to the router(s). For example, kube-aws and Google Container Engine both do this. On some other platforms-- Vagrant or bare metal, for instance-- this must either be accomplished manually or does not apply at all.
If a load balancer such as the one described above does exist (whether created automatically or manually) and if you intend on handling any long-running requests, the load balancer (or similar) may require some manual configuration to increase the idle connection timeout. Typically, this is most applicable to AWS and Elastic Load Balancers, but may apply in other cases as well. It does not apply to Google Container Engine, as the idle connection timeout cannot be configured there, but also works fine as-is.
If, for instance, router were installed on kube-aws, in conjunction with the rest of the Deis Workflow platform, this timeout should be increased to a recommended value of 1200 seconds. This will ensure the load balancer does not hang up on the client during long-running operations like an application deployment. Directions for this can be found here.
If using a Kubernetes distribution or underlying infrastructure that does not support the automated provisioning of a front-facing load balancer, operators will wish to manually configure a load balancer (or use other tricks) to route inbound traffic from beyond the cluster into the cluster to the platform's own router(s). There are many ways to accomplish this. The remainder of this section discusses three general options for accomplishing this.
This manually replicates the configuration that would be achieved automatically with some distributions on some infrastructure providers, as discussed above.
First, determine the "node ports" for the deis-router
service:
$ kubectl describe service deis-router --namespace=deis
This will yield output similar to the following:
...
Port: http 80/TCP
NodePort: http 32477/TCP
Endpoints: 10.2.80.11:80
Port: https 443/TCP
NodePort: https 32389/TCP
Endpoints: 10.2.80.11:443
Port: builder 2222/TCP
NodePort: builder 30729/TCP
Endpoints: 10.2.80.11:2222
Port: healthz 9090/TCP
NodePort: healthz 31061/TCP
Endpoints: 10.2.80.11:9090
...
The node ports shown above are high-numbered ports that are allocated on every Kubernetes worker node for use by the router service. The kube-proxy component on every Kubernetes node will listen on these ports and proxy traffic through to the corresponding port within an "endpoint--" that is, a pod running the Deis router.
If manually creating a load balancer, configure the load balancer to have all Kubernetes worker nodes in the back-end pool, and listen on ports 80, 443, and 2222 (port 9090 can be ignored). Each of these listeners should proxy inbound traffic to the corresponding node ports on the worker nodes. Ports 80 and 443 may use either HTTP/S or TCP as protocols. Port 2222 must use TCP.
With this configuration, the path a request takes from the end-user to an application pod is as follows:
user agent (browser) --> front-facing load balancer --> kube-proxy on _any_ Kubernetes worker node --> _any_ Deis router pod --> kube-proxy on that same node --> _any_ application pod
Option 2 differs only slightly from option 1, but is more efficient. As such, even operators who had a front-facing load balancer automatically provisioned on their infrastructure by Kubernetes might consider manually reconfiguring that load balancer as follows.
Deis router pods will listen on host ports 80, 443, 2222, and 9090 wherever they run. (They will not run on any worker nodes where all of these four ports are not available.) Taking advantage of this, an operator may completely dismiss the node ports discussed in option 1. The load balancer can be configured to have all Kubernetes worker nodes in the back-end pool, and listen on ports 80, 443, and 2222. Each of these listeners should proxy inbound traffic to the same ports on the worker nodes. Ports 80 and 443 may use either HTTP/S or TCP as protocols. Port 2222 must use TCP.
Additionally, a health check must be configured using the HTTP protocol, port 9090, and the /healthz
endpoint. With such a health check in place, only nodes that are actually hosting a router pods will pass and be included in the load balancer's pool of active back end instances.
With this configuration, the path a request takes from the end-user to an application pod is as follows:
user agent (browser) --> front-facing load balancer --> a Deis router pod --> kube-proxy on that same node --> _any_ application pod
Option 3 is similar to option 2, but does not actually utilize a load balancer at all. Instead, a DNS A record may be created that lists the public IP addresses of all Kubernetes worker nodes. This will leverage DNS round-robining to direct requests to all nodes. To guarantee all nodes can adequately route incoming traffic, the Deis router component should be scaled out by increasing the number of replicas specified in the deployment object to match the number of worker nodes. Anti-affinity should ensure exactly one router pod runs per worker node.
This configuration is not suitable for production. The primary use case for this configuration is demonstrating or evaluating Deis Workflow on bare metal Kubernetes clusters without incurring the effort to configure an actual front-facing load balancer.
The Helm Classic charts available for installing router (either with or without the rest of Deis Workflow) are intended to get users up and running as quickly as possible. As such, the charts do not strictly require any editing prior to installation in order to successfully bootstrap a cluster. However, there are some useful customizations that should be applied for use in production environments:
-
Specify a platform domain. Without a platform domain specified, any routable service specifying one or more non-fully-qualified domain names (not containing any
.
character) among itsrouter.deis.io/domains
will be matched using a regular expression of the form^{{ $domain }}\.(?<domain>.+)$
where{{ $domain }}
resolves to the non-fully-qualified domain name. By way of example, the idiosyncrasy that this exposes is that traffic bound for thefoo
subdomain of any domain would be routed to an application that lists the non-fully-qualified domain namefoo
among itsrouter.deis.io/domains
. While this behavior is not innately wrong, it may not be desirable. To circumvent this, specify a platform domain. This will cause routable services specifying one or more non-fully-qualified domain names to be matched, explicitly, as subdomains of the platform domain. Apart from remediating this minor idiosyncrasy, this is required in order to properly utilize a wildcard SSL certificate and may also result in a very modest performance improvement. -
Do you need to use SSL to secure the platform domain?
-
If using SSL, generate and provide your own dhparam. A dhparam is a secret key used in Diffie Hellman key exchange during the SSL handshake in order to help ensure perfect forward secrecy. The Helm Classic charts available for installing router (either with or without the rest of Deis Workflow) already include a dhparam, but recall that dhparams are intended to be secret. The dhparam included in the charts is marginally preferable to using Nginx's default dhparam only because it is lesser-known, but it is still publicly available in the deis/charts repository. As such, users wishing to run the router in production and use SSL are best off generating their own dhparam. After being generated, it should be base64 encoded and included as the value of the
dhparam
key in a Kubernetes secret nameddeis-router-dhparam
in the same namespace as the router itself.For example, to generate and base64 encode the dhparam on a Mac:
$ openssl dhparam -out dhparam.pem 1024 $ base64 dhparam.pem
To generate an even stronger key, use 2048 bits, but note that generating such a key will take a very long time-- possibly hours.
Include the base64 encoded dhparam in a secret:
apiVersion: v1 kind: Secret metadata: name: deis-router-dhparam namespace: deis labels: heritage: deis type: Opaque data: dhparam: <base64 encoded dhparam>
-
If using SSL, do you need to enforce the use of SSL?
-
If using SSL, do you need to enable strict transport security?
-
If using SSL, what grade does Qualys SSL Labs give you?
-
Should your router define and enforce a default whitelist? This may be advisable for routers governing ingress to a cluster that hosts applications intended for a limited audience-- e.g. applications for internal use within an organization.
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Do you need to scale the router? For greater availability, it's desirable to run more than one instance of the router. How many can only be informed by stress/performance testing the applications in your cluster. To increase the number of router instances from the default of one, increase the number of replicas specified by the
deis-router
deployment object. Do not specify a number of replicas greater than the number of worker nodes in your Kubernetes cluster.
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