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I am quite confused about the roles of Ingress and Load Balancer in Kubernetes.

As far as I understand Ingress is used to map incoming traffic from the internet to the services running in the cluster.

The role of load balancer is to forward traffic to a host. In that regard how does ingress differ from load balancer? Also what is the concept of load balancer inside kubernetes as compared to Amazon ELB and ALB?

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10 Answers 10

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Load Balancer: A kubernetes LoadBalancer service is a service that points to external load balancers that are NOT in your kubernetes cluster, but exist elsewhere. They can work with your pods, assuming that your pods are externally routable. Google and AWS provide this capability natively. In terms of Amazon, this maps directly with ELB and kubernetes when running in AWS can automatically provision and configure an ELB instance for each LoadBalancer service deployed.

Ingress: An ingress is really just a set of rules to pass to a controller that is listening for them. You can deploy a bunch of ingress rules, but nothing will happen unless you have a controller that can process them. A LoadBalancer service could listen for ingress rules, if it is configured to do so.

You can also create a NodePort service, which has an externally routable IP outside the cluster, but points to a pod that exists within your cluster. This could be an Ingress Controller.

An Ingress Controller is simply a pod that is configured to interpret ingress rules. One of the most popular ingress controllers supported by kubernetes is nginx. In terms of Amazon, ALB can be used as an ingress controller.

For an example, this nginx controller is able to ingest ingress rules you have defined and translate them to an nginx.conf file that it loads and starts in its pod.

Let's for instance say you defined an ingress as follows:

apiVersion: extensions/v1beta1
kind: Ingress
metadata:
  annotations:
   ingress.kubernetes.io/rewrite-target: /
 name: web-ingress
spec:
  rules:
  - host: kubernetes.foo.bar
    http:
      paths:
      - backend:
          serviceName: appsvc
          servicePort: 80
        path: /app

If you then inspect your nginx controller pod you'll see the following rule defined in /etc/nginx.conf:

server {
    server_name kubernetes.foo.bar;
    listen 80;
    listen [::]:80;
    set $proxy_upstream_name "-";
    location ~* ^/web2\/?(?<baseuri>.*) {
        set $proxy_upstream_name "apps-web2svc-8080";
        port_in_redirect off;

        client_max_body_size                    "1m";

        proxy_set_header Host                   $best_http_host;

        # Pass the extracted client certificate to the backend

        # Allow websocket connections
        proxy_set_header                        Upgrade           $http_upgrade;
        proxy_set_header                        Connection        $connection_upgrade;

        proxy_set_header X-Real-IP              $the_real_ip;
        proxy_set_header X-Forwarded-For        $the_x_forwarded_for;
        proxy_set_header X-Forwarded-Host       $best_http_host;
        proxy_set_header X-Forwarded-Port       $pass_port;
        proxy_set_header X-Forwarded-Proto      $pass_access_scheme;
        proxy_set_header X-Original-URI         $request_uri;
        proxy_set_header X-Scheme               $pass_access_scheme;

        # mitigate HTTPoxy Vulnerability
        # https://www.nginx.com/blog/mitigating-the-httpoxy-vulnerability-with-nginx/
        proxy_set_header Proxy                  "";

        # Custom headers

        proxy_connect_timeout                   5s;
        proxy_send_timeout                      60s;
        proxy_read_timeout                      60s;

        proxy_redirect                          off;
        proxy_buffering                         off;
        proxy_buffer_size                       "4k";
        proxy_buffers                           4 "4k";

        proxy_http_version                      1.1;

        proxy_cookie_domain                     off;
        proxy_cookie_path                       off;

    rewrite /app/(.*) /$1 break;
    rewrite /app / break;
    proxy_pass http://apps-appsvc-8080;

    }

Nginx has just created a rule to route http://kubernetes.foo.bar/app to point to the service appsvc in your cluster.

Here is an example of how to implement a kubernetes cluster with an nginx ingress controller. Hope this helps!

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  • I think last line proxy_pass apps-appsvc-8080; should be rather on port 80 instead. Also, often a LB like ELB is put in front of an Ingress Controller, why?
    – toto'
    Oct 19 '21 at 19:21
105

I found this very interesting article which explains the differences between NodePort, LoadBalancer and Ingress.

From the content present in the article:

LoadBalancer:

A LoadBalancer service is the standard way to expose a service to the internet. On GKE, this will spin up a Network Load Balancer that will give you a single IP address that will forward all traffic to your service.

If you want to directly expose a service, this is the default method. All traffic on the port you specify will be forwarded to the service. There is no filtering, no routing, etc. This means you can send almost any kind of traffic to it, like HTTP, TCP, UDP, Websockets, gRPC, or whatever.

The big downside is that each service you expose with a LoadBalancer will get its own IP address, and you have to pay for a LoadBalancer per exposed service, which can get expensive!

Ingress:

Ingress is actually NOT a type of service. Instead, it sits in front of multiple services and act as a “smart router” or entrypoint into your cluster.

You can do a lot of different things with an Ingress, and there are many types of Ingress controllers that have different capabilities.

The default GKE ingress controller will spin up a HTTP(S) Load Balancer for you. This will let you do both path based and subdomain based routing to backend services. For example, you can send everything on foo.yourdomain.com to the foo service, and everything under the yourdomain.com/bar/ path to the bar service.

Ingress is probably the most powerful way to expose your services, but can also be the most complicated. There are many types of Ingress controllers, from the Google Cloud Load Balancer, Nginx, Contour, Istio, and more. There are also plugins for Ingress controllers, like the cert-manager, that can automatically provision SSL certificates for your services.

Ingress is the most useful if you want to expose multiple services under the same IP address, and these services all use the same L7 protocol (typically HTTP). You only pay for one load balancer if you are using the native GCP integration, and because Ingress is “smart” you can get a lot of features out of the box (like SSL, Auth, Routing, etc)

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33

There are 4 ways to allow pods in your cluster to receive external traffic:
1.) Pod using HostNetworking: true and (Allows 1 pod per node to listen directly to ports on the host node. Minikube, bare metal, and rasberry pi's sometimes go this route which can allow the host node to listen on port 80/443 allow not using a load balancer or advanced cloud load balancer configurations, it also bypasses Kubernetes Services which can be useful for avoiding SNAT/achieving similar effect of externalTrafficPolicy: Local in scenarios where it's not supported like on AWS.)
2.) NodePort Service
3.) LoadBalancer Service (Which builds on NodePort Service)
4.) Ingress Controller + Ingress Objects (Which builds upon the above)

Lets say you have 10 websites hosted in your cluster and you want to expose them all to external traffic.
*If you use type LoadBalancer Service you'll spawn 10 HA Cloud load balancers (each costs money)
*If you use type Ingress Controller you'll spawn 1 HA Cloud load balancer(saves money), and it'll point to an Ingress Controller running in your cluster.

An Ingress Controller is:

  • A service of type Load Balancer backed by a deployment of pods running in your cluster.
  • Each pod does 2 things:
    1. Acts as a Layer 7 Load Balancer running inside your cluster. (Comes in many flavors Nginx is popular)
    2. Dynamically configures itself based on Ingress Objects in your cluster
      (Ingress Objects can be thought of as declarative configuration snippits of a Layer 7 Load Balancer.)

The L7 LB/Ingress Controller inside your cluster Load Balances / reverse proxies traffic to Cluster IP Services inside your Cluster, it can also terminate HTTPS if you have a Kubernetes Secret of type TLS cert, and Ingress object that references it.)

enter image description here

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  • in the pic, is the HA LB load balancing to nodes (e.g. in round robin) that in turn send these requests to the IC pod? What's the point to load balance if the IC runs on single pod?
    – toto'
    Oct 19 '21 at 19:30
  • External LB spreading traffic to NodePorts is just how Kubernetes is designed to take in external traffic. kube-proxy is what maps the NodePorts on the LAN to a Service in the Cluster. (Note: it's usually kube-proxy, Cilium CNI has an alternative). Kubernetes Services then act as Inner Cluster LBs, so once kube-proxy brings LB service's traffic to inner cluster network, inner cluster service starts LB'ing to ingress pods identified using labels. Ingress Controllers pods are usually managed by deployments, so you can start with 1 Ingress Controller pod, but scale up as needed.
    – neokyle
    Oct 20 '21 at 13:29
  • Also whats the point is that this is scalable LB architecture. L7 LBs don't scale as well as L4 LBs. So a common LB architecture pattern to make L7 LB's scale is to put an L4 LB in front of L7 LBs. Imagine the HA CLB as a L4 LB. And the Ingress Controller pods as L7 LB (backed by deployment + horizontal pod autoscaler), it's an architecture that works well at scale.
    – neokyle
    Oct 20 '21 at 13:31
  • Ok thanks. Follow up question then. If the IC can be scaled and run on many pods how do we implement sticky sessions (normal for an L7 LB) if in front of it there is an L4 LB (that does not understand protocols above TCP)?
    – toto'
    Oct 21 '21 at 10:59
  • 2
    In general sticky sessions aren't recommended as they limit ability to scale / they're a trick to workaround poor architectural designs In my opinion, but if you had to use them. How is implementation specific you'd need to google the documentation associated with your Kubernetes service of type LB. Most L4 LBs have some L7 awareness. AWS NLB (network = OSI L4), HA Proxy started off as a L4 LB, but has slowly grown to have a few L7 features. Both support sticky sessions. There's also the option of using L7 CSP LB to forward to L7 Ingress LB, L7 CSP LBs tend to come with traffic SLAs.
    – neokyle
    Oct 21 '21 at 13:34
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TL:DR

  1. Ingress sits between the public network (Internet) and the Kubernetes services that publicly expose our Api's implementation.
  2. Ingress is capable to provide Load Balancing, SSL termination, and name-based virtual hosting.
  3. Ingress capabilities allows to securely expose multiple API's or Applications from a single domain name.

Let's start with practical use case: you have multiple Apis backed by service implementation packages (ASIP for clariy and brevity) to deploy under one single domain name. As you are a cutting edge developer, you implemented a micro-services architecture that requires separate deployments for each ASIP so they can be upgraded or scaled individually. Of course,these ASIPs are encapsulated in individual docker container and available to Kubernetes (K8s) from container repository.

Let's say now that you want to deploy this on Google's GKE K8s. To implement sustained availability, each ASIP instance (replica) is deployed on different nodes (VM) where each VM has it's own cloud internal IP address. Each ASIP deployment is configured in an aptly name "deployment.yaml" file where you declaratively specify, among other things, the number of replicas of the given ASIP K8s should deploy.

The next step is to expose the API to the ouside world and funnel requests to one of the deployed ASIP instance. Since we have many replicas of the same ASIP running on different nodes, we need something that will distribute the request among those replicas. To resolve this, we can create and apply a "service.yaml" file that will configure a K8s service (KServ) that will be externally exposed and accessible through an IP address. This KServ will take charge of the API's request distribution among it's configured ASIPs. Note that a KServ will be automatically reconfigured by the K8s master when an ASIP's node fail and is restarted. Internal IP address are never reused in such case and the KServ must be advised of the new ASIP's deployment location.

But we have other Api service packages that shall be exposed on the same domain name. Spinning a new KServ will create a new external IP address and we won't be able to expose it on the same domain name. Well, this is where Ingress comes in.

Ingress sit's between the Internet and all the KServices we expose to to the outside world. Ingress is capable to provide load balancing, SSL termination and name-based virtual hosting. The latter capacity is able to route an incoming request to the right service by analysing it's URL. Of Course, Ingress must be configured and applied with an... "ingress.yaml" file that will specify the rewrites and the routes required to send a request to the right KServ.

Internet -> Ingress -> K8s Services -> Replicas

So, with the right ingress, KServices and ASIPs configuration, we can securely expose many API's using the same domain name.

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19

In simple words, load balancer distributes the requests among multiple backend services (of same type) whereas ingress is more like an API gateway (reverse proxy) which routes the request to a specific backend service based on, for instance, the URL.

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  • ALB in AWS will use path to route similar to API gateway with proxy.
    – Mukus
    Dec 19 '21 at 20:28
18

Ingress: Ingress Object + Ingress Controller

Ingress Resource:

Just like a Service Resource, except it does not do anything on its own because an Ingress Controller is not included by default. An Ingress Resource just describes a way to route Layer 7 traffic into your cluster, by specifying things like the request path, request domain, and target kubernetes service, while adding a service object may actually creates services because a service controller is included in Kubernetes by default.

Ingress Controller:

A Service which:

  1. listens on specific ports (usually 80 and 443) for web traffic
  2. Listens for the creation, modification, or deletion of Ingress Resources
  3. Creates internal L7 routing rules based on these Ingress Resources

In example, the Nginx Ingress Controller, could use a service to listen on port 80 and 443 and then read new Ingress Resources and parse them into new server{} sections which it dynamically places into it's nginx.conf

LoadBalancer: External Load Balancer Provider + Service Type

External Load Balancer Provider:

External Load Balancer Providers are usually configured in clouds such as AWS and GKE and provide a way to assign external IPs through the creation of external load balancers. This functionality can be used by designating a service as type "LoadBalancer".

Service Type:

When the service type is set to LoadBalancer, Kubernetes attempts to create and then configure an external load balancer with entries for the Kubernetes pods, thereby assigning them external IPs.

The Kubernetes service controller automates the creation of the external load balancer, health checks (if needed), firewall rules (if needed) and retrieves the external IP of the newly created or configured LoadBalancer which was allocated by the cloud provider and populates it in the service object.

An additional cloud controller may be installed on the cluster and be assigned with reading service resources and their annotations in order to automatically deploy and configure cloud load balancers that will receive traffic for the kubernetes service.

Relationships:

Ingress Controller Services are often provisioned as LoadBalancer type, so that http and https requests can be proxied / routed to specific internal services through an external ip.

However, a LoadBalancer is not strictly needed for this. Since, through the use of hostNetwork or hostPort you can technically bind a port on the host to a service (allowing you to visit it via the hosts external ip:port). Though officially this is not recommended as it uses up ports on the actual node.

References:

https://kubernetes.io/docs/concepts/configuration/overview/#services

https://kubernetes.io/docs/tasks/access-application-cluster/create-external-load-balancer/

https://kubernetes.io/docs/tasks/access-application-cluster/create-external-load-balancer/#external-load-balancer-providers

https://kubernetes.io/docs/concepts/services-networking/ingress/

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LoadBalancer : It's a standard way to expose a service to the internet.

Any traffic (HTTP / TCP / UDP / Websockets/ gRPC etc) on the port we specify, will be forwarded to the service without any filtering/routing.

enter image description here


Ingress : It sits in front of multiple services and act as a router / entry-point into our cluster.

It let's us configure set of rules to pass to the controller (NGINX-Based Ingress Controllers / Envoy ingress controller / GCP Ingress Controller / Trefik / Istio) that is listening for them and is really useful if we want to expose multiple services under the same IP address.

enter image description here

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Feature Ingress Load Balancer
Protocal HTTP level (Network layer 7) Network layer 4
Additional Features cookie-based session affinity, Ingress rules, Resource backends, Path types Only balance the load
Dependency Ingress controller need to be running. Different Kubernetes environments use different implementations of the controller, but several don’t provide a default controller at all. No dependency, Built-in support with K8
YAML manifest There is separate API for it. apiVersion: networking.k8s.io/v1 type: LoadBalancer
How it work Client connected to one of the pods through Ingress controller. The client first performed a DNS lookup of example.com, and the DNS server (or the local operating system) returned the IP of the Ingress controller. The client then sent an HTTP request to the Ingress controller and specified example.com in the Host header. From that header, the controller determined which service the client is trying to access, looked up the pod IPs through the Endpoints object associated with the service, and forwarded the client’s request to one of the pods. The load balancer redirects traffic to the node port across all the nodes. Clients connect to the service through the load balancer’s IP.
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Loadbalancer service: is a layer 4 proxy (TCP, UDP,..). It runs outside Kubernetes cluster-network. It doesn't have features of layer 7: CircuitBreaker, measure number of request, request's latency, failure, routing,...

ingress: is a layer 7 proxy (http, https, gRPC,..). It is an application in a pod inside Kubernetes cluster-network. If the ingress pod dies, Kubernetes will restart it or move it to other node in the cluster.

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Pods have their own IP:PORT but it is dynamic in nature and changes if deleted or redeployed.

Services are assigned ClusterIPor NodePort(a port in a VM where service resource is created) which can be mapped to set of pods or other backend [see: headless services]

  • To access correct Pod use ClusterIP(from within clutser)

  • NodePort can be used to access pods from outside of the cluster

LoadBalancer[External/Internal]: provided by cloud providers points to either ClusterIP or NodePort. You can access the service by using LB's IP

LB ~> SERVICE(ClusterIP or NodePort) ~> POD

Ingress resource is an entrypoint to cluster.A LB can listen to ingress rules and can route to specific service.[see this example]

LB(Ingress-managed) ~> SERVICE(ClusterIP or NodePort) ~> POD

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