How to configure HTTP load balancer with HAProxy on Linux

Last updated on December 4, 2020 by Dan Nanni

Increased demand on web based applications and services are putting more and more weight on the shoulders of IT administrators. When faced with unexpected traffic spikes, organic traffic growth, or internal challenges such as hardware failures and urgent maintenance, your web application must remain available, no matter what. Even modern devops and continuous delivery practices can threaten the reliability and consistent performance of your web service.

Unpredictability or inconsistent performance is not something you can afford. But how can we eliminate these downsides? In most cases a proper load balancing solution will do the job. And today I will show you how to set up HTTP load balancer using HAProxy.

What is HTTP load balancing?

HTTP load balancing is a networking solution responsible for distributing incoming HTTP or HTTPS traffic among servers hosting the same application content. By balancing application requests across multiple available servers, a load balancer prevents any application server from becoming a single point of failure, thus improving overall application availability and responsiveness. It also allows you to easily scale in/out an application deployment by adding or removing extra application servers with changing workloads.

Where and when to use load balancing?

As load balancers improve server utilization and maximize availability, you should use it whenever your servers start to be under high loads. Or if you are just planning your architecture for a bigger project, it's a good habit to plan usage of load balancer upfront. It will prove itself useful in the future when you need to scale your environment.

What is HAProxy?

HAProxy is a popular open-source load balancer and proxy for TCP/HTTP servers on GNU/Linux platforms. Designed in a single-threaded event-driven architecture, HAproxy is capable of handling 10G NIC line rate easily, and is being extensively used in many production environments. Its features include automatic health checks, customizable load balancing algorithms, HTTPS/SSL support, session rate limiting, etc.

What are we going to achieve in this tutorial?

In this tutorial, we will go through the process of configuring a HAProxy-based load balancer for HTTP web servers.

Prerequisites

You will need at least one, or preferably two web servers to verify functionality of your load balancer. We assume that backend HTTP web servers are already up and running.

Install HAProxy on Linux

For most distributions, we can install HAProxy using your distribution's package manager.

Install HAProxy on Debian

In Debian we need to add backports for Wheezy. To do that, please create a new file called backports.list in /etc/apt/sources.list.d with the following content:

deb http://cdn.debian.net/debian wheezy­backports main 

Refresh your repository data and install HAProxy.

# apt­ get update 
# apt ­get install haproxy 

Install HAProxy on Ubuntu

# apt ­get install haproxy 

Install HAProxy on CentOS and RHEL

# yum install haproxy 

Configure HAProxy

In this tutorial, we assume that there are two HTTP web servers up and running with IP addresses 192.168.100.2 and 192.168.100.3. We also assume that the load balancer will be configured at a server with IP address 192.168.100.4.

To make HAProxy functional, you need to change a number of items in /etc/haproxy/haproxy.cfg. These changes are described in this section. In case some configuration differs for different GNU/Linux distributions, it will be noted in the paragraph.

1. Configure Logging

One of the first things you should do is to set up proper logging for your HAProxy, which will be useful for future debugging. Log configuration can be found in the global section of /etc/haproxy/haproxy.cfg. The following are distro-specific instructions for configuring logging for HAProxy.

Configure Logging on CentOS or RHEL:

To enable logging on CentOS/RHEL, replace:

log         127.0.0.1 local2 

with:

log         127.0.0.1 local0 

The next step is to set up separate log files for HAProxy in /var/log. For that, we need to modify our current rsyslog configuration. To make the configuration simple and clear, we will create a new file called haproxy.conf in /etc/rsyslog.d/ with the following content.

$ModLoad imudp 
$UDPServerRun 514  
$template Haproxy,"%msg%n" 
local0.=info ­/var/log/haproxy.log;Haproxy 
local0.notice ­/var/log/haproxy­status.log;Haproxy 
local0.* ~ 

This configuration will separate all HAProxy messages based on the $template to log files in /var/log. Now restart rsyslog to apply the changes.

# service rsyslog restart  

Debian or Ubuntu:

To enable logging for HAProxy on Debian or Ubuntu, replace:

log /dev/log        local0 
log /dev/log        local1 notice 

with:

log         127.0.0.1 local0 

Next, to configure separate log files for HAProxy, edit a file called haproxy.conf (or 49-haproxy.conf in Debian) in /etc/rsyslog.d/ with the following content.

$ModLoad imudp 
$UDPServerRun 514  
$template Haproxy,"%msg%n" 
local0.=info ­/var/log/haproxy.log;Haproxy 
local0.notice ­/var/log/haproxy­status.log;Haproxy 
local0.* ~ 

This configuration will separate all HAProxy messages based on the $template to log files in /var/log. Now restart rsyslog to apply the changes.

# service rsyslog restart  

2. Setting Defaults

The next step is to set default variables for HAProxy. Find the defaults section in /etc/haproxy/haproxy.cfg, and replace it with the following configuration.

    defaults 
    log     global 
    mode    http 
    option  httplog 
    option  dontlognull 
    retries 3 
    option redispatch 
    maxconn 20000 
    contimeout      5000 
    clitimeout      50000 
    srvtimeout      50000

The configuration stated above is recommended for HTTP load balancer use, but it may not be the optimal solution for your environment. In that case, feel free to explore HAProxy man pages to tweak it.

3. Webfarm Configuration

Webfarm configuration defines the pool of available HTTP servers. Most of the settings for our load balancer will be placed here. Now we will create some basic configuration, where our nodes will be defined. Replace all of the configuration from frontend section until the end of file with the following code:

listen webfarm *:80 
       mode http 
       stats enable 
       stats uri /haproxy?stats 
       stats realm Haproxy Statistics 
       stats auth haproxy:stats 
       balance roundrobin 
       cookie LBN insert indirect nocache 
       option httpclose 
       option forwardfor 
       server web01 192.168.100.2:80 cookie node1 check 
       server web02 192.168.100.3:80 cookie node2 check 

The line listen webfarm *:80 defines on which interfaces our load balancer will listen. For the sake of the tutorial, I've set that to * which makes the load balancer listen on all our interfaces. In a real world scenario, this might be undesirable and should be replaced with an interface that is accessible from the internet.

stats enable 
stats uri /haproxy?stats 
stats realm Haproxy Statistics 
stats auth haproxy:stats 

The above settings declare that our load balancer statistics can be accessed on http://<load-balancer-IP>/haproxy?stats. The access is secured with a simple HTTP authentication with login name haproxy and password stats. These settings should be replaced with your own credentials. If you don't need to have these statistics available, then completely disable them.

Here is an example of HAProxy statistics.

The line balance roundrobin defines the type of load balancing we will use. In this tutorial we will use simple round robin algorithm, which is fully sufficient for HTTP load balancing. HAProxy also offers other types of load balancing:

The line cookie LBN insert indirect nocache makes our load balancer store persistent cookies, which allows us to pinpoint which node from the pool is used for a particular session. These node cookies will be stored with a defined name. In our case, I used LBN, but you can specify any name you like. The node will store its string as a value for this cookie.

server web01 192.168.100.2:80 cookie node1 check 
server web02 192.168.100.3:80 cookie node2 check 

The above part is the definition of our pool of web server nodes. Each server is represented with its internal name (e.g., web01, web02). IP address, and unique cookie string. The cookie string can be defined as anything you want. I am using simple node1, node2 ... node(n).

Start HAProxy

When you are done with the configuration, it's time to start HAProxy and verify that everything is working as intended.

Start HAProxy on Centos/RHEL

Enable HAProxy to be started after boot and turn it on using:

# chkconfig haproxy on 
# service haproxy start 

And of course don't forget to enable port 80 in the firewall as follows.

Firewall on CentOS/RHEL 7:

# firewall­cmd ­­permanent ­­zone=public ­­add­port=80/tcp 
# firewall­cmd ­­reload 

Firewall on CentOS/RHEL 6:

Add following line into section :OUTPUT ACCEPT of /etc/sysconfig/iptables:

­A INPUT ­m state ­­state NEW ­m tcp ­p tcp ­­dport 80 ­j ACCEPT 

and restart iptables:

# service iptables restart 

Start HAProxy on Debian

Start HAProxy with:

# service haproxy start 

Don't forget to enable port 80 in the firewall by adding the following line into /etc/iptables.up.rules:

­A INPUT ­p tcp ­­dport 80 ­j ACCEPT 

Start HAProxy on Ubuntu

Enable HAProxy to be started after boot by setting ENABLED option to 1 in /etc/default/haproxy:

ENABLED=1 

Start HAProxy:

# service haproxy start

and enable port 80 in the firewall:

# ufw allow 80 

Test HAProxy

To check whether HAproxy is working properly, we can do the following.

First, prepare test.php file with the following content:

<?php
header('Content-Type: text/plain');
echo "Server IP: ".$_SERVER['SERVER_ADDR'];
echo "nX-Forwarded-for: ".$_SERVER['HTTP_X_FORWARDED_FOR'];
?>

This PHP file will tell us which server (i.e., load balancer) forwarded the request, and what backend web server actually handled the request.

Place this PHP file in the root directory of both backend web servers. Now use curl command to fetch this PHP file from the load balancer (192.168.100.4).

$ curl http://192.168.100.4/test.php

When we run this command multiple times, we should see the following two outputs alternate (due to the round robin algorithm).

Server IP: 192.168.100.2
X-Forwarded-for: 192.168.100.4
Server IP: 192.168.100.3
X-Forwarded-for: 192.168.100.4

If we stop one of the two backend web servers, the curl command should still work, directing requests to the other available web server.

Summary

By now you should have a fully operational load balancer that supplies your web nodes with requests in round robin mode. As always, feel free to experiment with the configuration to make it more suitable for your infrastructure. I hope this tutorial helped you to make your web projects more resistant and available.

As most of you already noticed, this tutorial contains settings for only one load balancer. Which means that we have just replaced one single point of failure with another. In real life scenarios you should deploy at least two or three load balancers to cover for any failures that might happen, but that is out of the scope of this tutorial right now.

If you have any questions or suggestions feel free to post them in the comments and I will do my best to answer or advice.

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