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Azure Load Balancer – Abstracted Azure resource which is scalable and resilient. Dynamically splits traffic between the two FortiGates.
Virtual Network – 10.40.0.0/16, also known as VNET
Public Facing Network – 10.40.1.0/24
Protected Network – 10.40.2.0/24
Availability Set – Method of grouping resources within Azure to ensure that they are hosted on separate physical hardware in order to ensure that at any given time (even during upgrades and maintenance) at least one of the set will remain up.
FortiGate – Azure certified virtual appliance running the same OS which is used on our hardware appliances. These will be referenced as FortiGate-A and FortiGate-B.
FortiManager – Dedicated policy and configuration manager, used to keep the configuration in sync between the two FortiGates.
Utilize the FortiGate HA template which is available in the Microsoft Azure Marketplace to deploy the network resources and FortiGates as depicted in the diagram.
Azure Load Balancer
All traffic coming from outside of Azure will pass through the load balancer first. The load balancer uses Network Address Translation and Port Address Translation (NAT/PAT) to connect a single public IP address to the Azure VNET. Within the Azure portal there are two options for configuring these NAT rules. The first is called “Inbound NAT rules.” The second is termed “Load balancing Rules”
These rules are applied to a specific host and are not load balanced. As such, these are typically used for management. The template uses ports 443 and 22 for management of FortiGate-A. Ports 8443 and 8022 are similarly directed at FortiGate-B. Once the FortiGates are configured, you can change these ports. For example, if you want to use port 443 for internal web services, you could configure an alternate port on FortiGate-A for management, and modify this rule to use that new port. Once you change the port here, you can then create a new Load balancing rule to direct 443 to the pair of FortiGates.
These rules also use PAT, but rather than being directed at a specific host, they are directed at a collection of virtual machines called a backend pool. In this case, the pool consists of FortiGate-A and FortiGate-B. These rules are necessary to provide high availability and load balancing for any given service. Referencing the above example – after you have freed up port 443, you would create a new Load balancing rule, configured on port 443 and directed to the FortiGate backend pool.
The architecture described here is given to provide a highly available secure solution within a networking environment that doesn't support traditional HA mechanisms. If you enable HA features in the FortiGate GUI, you will likely lose connectivity and need to redeploy. See below in the comments for additional dialogue on the various reasons for this.
If you choose PAYG during deployment, you will start with fully licensed FortiGates that are billed directly by Microsoft. The hourly prices are available in the marketplace description.
However, if you choose BYOL (Bring your own license), the first step of configuration is to install a license. Connect to the web-based management interface at the public IP address assigned to the Azure Load Balancer. This interface will be available via port 443 - each FortiGate has NAT rules for ports 22 and 443 configured through the load balancer. The first public IP which you selected (or created) will direct to FortiGate-A and the second will direct to FortiGate-B. If desired, you can modify the ports used through the load balancer configuration in the Azure portal.
Once connected, you will be prompted to install a license file. After you have uploaded the license file, wait for the FortiGate to reboot and connect to the FortiGuard services. Full FortiGuard synchronization can take up to 30 minutes. However, you should be able to connect and continue configuration within about 5 minutes.
Note: The BYOL Marketplace template does not come with a license. In order to obtain a license, you will need to work with your Fortinet representative or network security partner. Alternately, you can email azure@fortinet.com
If you would like to change the management ports in order to allow those ports to be forwarded to internal resources, you will need to change both on the FortiGate (select System -> Admin -> Settings and adjust accordingly), and on the load balancer NAT rules configuration in the Azure portal.
In order to allow outbound communication from hosts on the Protected Network to the internet or other external hosts, you will need to configure a policy:
For additional information on granular configuration, security profiles, etc., please see the FortiOS Handbook: http://docs.fortinet.com/d/fortigate-fortios-handbook-the-complete-guide-to-fortios-5.2
To enable traffic coming from the internet, you will need to configure PAT on the FortiGates. The first step will be to create a Virtual IP:
Once you have the Virtual IP configured, you need to create a new policy:
Finally, configure a new load balancer rule on the Azure load balancer. This can be done through the Azure portal, powershell, Azure CLI, or even REST APIs. However, you do so, be sure to enable floating IP/Direct server return on the load balancer rule. This enables the load balancer to forward the traffic without changing the destination IP address (so the FortiGate VIP will match traffic destined to the original public IP destination). This has the benefit of allowing you to reuse the same port (example TCP 443) with multiple VIPs. It also can be used with FGSP to synchronize state between the two FortiGates in certain asymmetric configurations.
Through the use of the Azure Load Balancer and the source NAT on incoming traffic to the FortiGates (described above), we are able to achieve high availability for incoming connections. For many common services this is adequate. However, for services requiring the ability to create outbound connections like SMTP servers or Web servers which communicate with other databases, etc., there’s an additional mechanism that needs to be deployed.
In order to force internal->external traffic to route through the FortiGate, we use an Azure feature called User Defined Routes (UDRs). This allows us to specify an alternative to the default Azure router, but it only allows a single router per route. If that router is not available, the traffic gets dropped. Thus, to support highly available internal->external connections we need to programatically change that UDR. There are various ways to do this.
--Note--
Azure has a recommended deployment option for this. However, it's not widely used and by all accounts both difficult and expensive. Here are details on that.
https://github.com/mspnp/ha-nva
Also, Azure now supports internal load balancers as UDR next hops. So, depending on your deployment adding an internal load balancer may be preferable for providing outbound and east/west HA. It has faster failover time (max 10 seconds vs. minimum 30 seconds), and can be used to scale FortiGates horizontally. Currently, the internal load balancer, while it functions at layer 3, must be configured on a per UDP/TCP port at layer 4. Thus, any solution which leverages a dual load balancer, must use source-NAT on the FortiGate for all traffic.
Here is the oldest and most widely deployed solution:
The fastest method utilizes an in-VNet virtual server to act as a Software Defined Network (SDN) controller. It does so by running a monitor script and changing the Azure UDR in the case that FortiGate-A becomes inaccessible. This controller needs to have access to the internet regardless of the status of either FortiGate, so it is typically placed int the 'outside' subnet. The testing and PoCs that we have done have been on A0 Ubuntu VMs. The sample script attached to this post is a Unix shell script that leverages the Azure CLI. This is provided as a sample and will need to be customized to fit your environment. You could also create a powershell script and run the same process from a Windows VM (or do something similar from an Azure runbook).
Prior to running the script on an Ubuntu server, you will need to complete the following:
- Install Azure CLI tools
sudo apt-get install nodejs-legacy
sudo apt-get install npm
sudo npm install -g azure-cli
- Install JQ
sudo apt-get install jq
- Authenticate to Azure. Note: this requires an Azure AD account. For more information: https://azure.microsoft.com/en-us/documentation/articles/resource-group-create-work-id-from-personal...
azure login -u
- Set Azure CLI to ARM mode
azure config mode arm
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Hi Martin,
Does this mean customer has to use Azure load balancer compulsory to achieve HA of FortiGate? Is it possible to implement HA in same fashion what we do in physical appliances? If possible, can you please share sample configuration?
Regds,
Pratik Soni
Hi Pratik,
Traditional HA is not currently possible within the public cloud. So, the architecture described in the original post is an option to still provide a highly available or redundant solution within the inherit limitations of Azure.
Here are the key limitations that make traditional HA impossible:
- No access to layer 2 (gratuitous ARP or any ARP manipulation isn't possible).
- No multicast
- No Virtual IP nor IP mobility
- Limited ability to manipulate intraVNet routing.
So, to answer to your first question - Yes, in order to provide a resilient security environment to public, internet-based clients, an Azure load balancer is required. There is an architecture designed for east/west inspection between virtual networks (not north/south - the Azure load balancer is still required for traffic sourced from public IPs) where you can utilize a combination of IPSec, BGP, and FGSP to provide immediate failover and session synchronization. I'm working on some documentation for this and will post a link in here soon.
In Reply to Martin Twombly:
[...]
the Azure load balancer is still required for traffic sourced from public IPs) where you can utilize a combination of IPSec, BGP, and FGSP to provide immediate failover and session synchronization. I'm working on some documentation for this and will post a link in here soon.
Hello Martin,
Great post ! Do you have any news about this doc ? I am currently more and more questioned about "HA" in Azure and looking for as much information as I can get.
Yann
Hi Martin,
I was hoping you could assist with the script as the UDR and servers sit in a different RG than the HA Fortinet's. We have relatively complex environment being built out in an NCUS and WEU Azure tenancy. The client will require many site to site VPN's to onprem which leverage a UDR.
Thanks,
-Bobby
Bobby,
Resource Groups are just organizational container abstract concepts.
The FortiNet can be in it's own RG and other devices in their own and they talk properly as long as they are within the same subscription.
Thank you, Leif!
I think my concern was more so around routing, and what options there were to update the UDR for next hop IP. I think we are going to use an internal load balancer with a private IP, and point the UDR to that VM as the next hop.
Thanks,
-Bobby
Martin
In the section below, should the ports on steps 4 and 6 be different?
Once you have the Virtual IP configured, you need to create a new policy:
Thanks
Richard
Hi Richard,
Yes, you are correct. Thank you for catching that!
I'll update it now.
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