Always On VPN Multisite with Azure Traffic Manager

Always On VPN Multisite with Azure Traffic ManagerEliminating single points of failure is crucial to ensuring the highest levels of availability for any remote access solution. For Windows 10 Always On VPN deployments, the Windows Server 2016 Routing and Remote Access Service (RRAS) and Network Policy Server (NPS) servers can be load balanced to provide redundancy and high availability within a single datacenter. Additional RRAS and NPS servers can be deployed in another datacenter or in Azure to provide geographic redundancy if one datacenter is unavailable, or to provide access to VPN servers based on the location of the client.

Multisite Always On VPN

Unlike DirectAccess, Windows 10 Always On VPN does not natively include support for multisite. However, enabling multisite geographic redundancy can be implemented using Azure Traffic Manager.

Azure Traffic Manager

Traffic Manager is part of Microsoft’s Azure public cloud solution. It provides Global Server Load Balancing (GSLB) functionality by resolving DNS queries for the VPN public hostname to an IP address of the most optimal VPN server.

Advantages and Disadvantages

Using Azure Traffic manager has some benefits, but it is not with some drawbacks.

Advantages – Azure Traffic Manager is easy to configure and use. It requires no proprietary hardware to procure, manage, and support.

Disadvantages – Azure Traffic Manager offers only limited health check options. Today, only HTTP, HTTP, and TCP protocols can be used to perform endpoint health checks. There is no option to use UDP or PING, making monitoring for IKEv2 a challenge.

Note: This scenario assumes that RRAS with Secure Socket Tunneling Protocol (SSTP) or another third-party TLS-based VPN server is in use. If IKEv2 is to be supported exclusively, it will still be necessary to publish an HTTP or HTTPS-based service for Azure Traffic Manager to monitor site availability.

Traffic Routing Methods

Azure Traffic Manager provide four different methods for routing traffic.

Priority – Select this option to provide active/passive failover. A primary VPN server is defined to which all traffic is routed. If the primary server is unavailable, traffic will be routed to another backup server.

Weighted – Select this option to provide active/active failover. Traffic is routed to all VPN servers equally, or unequally if desired. The administrator defines the percentage of traffic routed to each server.

Performance – Select this option to route traffic to the VPN server with the lowest latency. This ensures VPN clients connect to the server that responds the quickest.

Geographic – Select this option to route traffic to a VPN server based on the VPN client’s physical location.

Multivalue – Select this option when endpoints must use IPv4 or IPv6 addresses.

Subnet – Select this option to map DNS responses to the client’s source IP address.

Configure Azure Traffic Manager

Open the Azure management portal and follow the steps below to configure Azure Traffic Manager for multisite Windows 10 Always On VPN.

Create a Traffic Manager Resource

  1. Click Create a resource.
  2. Click Networking.
  3. Click Traffic Manager profile.

Create a Traffic Manager Profile

  1. Enter a unique name for the Traffic Manager profile.
  2. Select an appropriate routing method (described above).
  3. Select a subscription.
  4. Create or select a resource group.
  5. Select a resource group location.
  6. Click Create.

Always On VPN Multisite with Azure Traffic Manager

Important Note: The name of the Traffic Manager profile cannot be used by VPN clients to connect to the VPN server, since a TLS certificate cannot be obtained for the trafficmanager.net domain. Instead, create a CNAME DNS record that points to the Traffic Manager FQDN and ensure that name matches the subject or a Subject Alternative Name (SAN) entry on the VPN server’s TLS and/or IKEv2 certificates.

Endpoint Monitoring

Open the newly created Traffic Manager profile and perform the following tasks to enable endpoint monitoring.

  1. Click Configuration.
  2. Select HTTPS from the Protocol drop-down list.
  3. Enter 443 in the Port field.
  4. Enter /sra_%7BBA195980-CD49-458b-9E23-C84EE0ADCD75%7D/ in the Path field.
  5. Enter 401-401 in the Expected Status Code Ranges field.
  6. Update any additional settings, such as DNS TTL, probing interval, tolerated number of failures, and probe timeout, as required.
  7. Click Save.

aovpn_traffic_manager_multisite_001

Endpoint Configuration

Follow the steps below to add VPN endpoints to the Traffic Manager profile.

  1. Click Endpoints.
  2. Click Add.
  3. Select External Endpoint from the Type drop-down list.
  4. Enter a descriptive name for the endpoint.
  5. Enter the Fully Qualified Domain Name (FQDN) or the IP address of the first VPN server.
  6. Select a geography from the Location drop-down list.
  7. Click OK.
  8. Repeat the steps above for any additional datacenters where VPN servers are deployed.

Always On VPN Multisite with Azure Traffic Manager

Summary

Implementing multisite by placing VPN servers is multiple physical locations will ensure that VPN connections can be established successfully even when an entire datacenter is offline. In addition, active/active scenarios can be implemented, where VPN client connections can be routed to the most optimal datacenter based on a variety of parameters, including current server load or the client’s current location.

Additional Information

Windows 10 Always On VPN Hands-On Training Classes

Always On VPN Routing Configuration

Windows 10 Always On VPN Routing ConfigurationWhen configuring Windows 10 Always On VPN, the administrator must choose between force tunneling and split tunneling. When force tunneling is used, all network traffic from the VPN client is routed over the VPN tunnel. When split tunneling is used, the VPN client must be configured with the necessary IP routes to establish remote network connectivity to on-premises resources. How those routes are established is a common source of confusion. This article provides guidance for properly configuring routing for Always On VPN clients.

Class Based Routing

IP addresses are assigned to Windows 10 Always On VPN clients from either a static pool of addresses configured by the administrator or by DHCP. If split tunneling is enabled, the client will also be assigned a class-based route that is derived from the IP address assigned to it by the VPN server, by default. If the client is assigned an IP address from the Class A network, a corresponding /8 prefix is used. For Class B networks a /16 prefix is defined, and for Class C networks a /24 prefix is used.

As an example, if the VPN server assigns the client an IP address of 10.21.12.103, a route to the 10.0.0.0/8 network is added to the client’s routing table, as shown here.

Windows 10 Always On VPN Routing Configuration

Complex Networks

This default class-based route is of limited use though, and is only applicable when the internal network is simple and VPN clients are assigned IP addresses from the same subnet class. In the example above, if the entire internal network resides in the 10.0.0.0/8 Class A address space, all resources will be reachable by the VPN client. Any resources in the Class B or Class C subnet ranges would be unreachable without additional configuration.

Route Configuration

To configure routing for Windows 10 Always On VPN clients, first disable the default class-based route by defining the following element in ProfileXML as shown here.

<VPNProfile>
   <NativeProfile>
      <DisableClassBasedDefaultRoute>true</DisableClassBasedDefaultRoute>
   </NativeProfile>
</VPNProfile>

Next, enable specific routes as needed by defining the following element(s) in ProfileXML. The example below defines routes for all private RFC 1918 networks.

<VPNProfile>
   <Route>
      <Address>10.0.0.0</Address>
      <PrefixSize>8</PrefixSize>
   </Route>
   <Route>
      <Address>172.16.0.0</Address>
      <PrefixSize>12</PrefixSize>
   </Route>
   <Route>
      <Address>192.168.0.0</Address>
      <PrefixSize>16</PrefixSize>
   </Route>
</VPNProfile>

Once implemented, the VPN client’s routing table will appear as shown here.

Windows 10 Always On VPN Routing Configuration

Summary

Proper routing is crucial for ensuring full network connectivity and access to internal resources for Windows 10 Always On VPN clients. When split tunneling is employed, avoid using the default class-based route and instead define specific routes using ProfileXML as required.

Additional Information

Always On VPN Client DNS Server Configuration

Deploying Windows 10 Always On VPN with Microsoft Intune

Windows 10 Always On VPN Certificate Requirements for IKEv2

Windows 10 Always On VPN Certificate Requirements for SSTP

Always On VPN SSL Certificate Requirements for SSTP

Always On VPN Certificate Requirements for SSTPThe Windows Server 2016 Routing and Remote Access Service (RRAS) is commonly deployed as a VPN server for Windows 10 Always On VPN deployments. Using RRAS, Always On VPN administrators can take advantage of Microsoft’s proprietary Secure Socket Tunneling Protocol (SSTP) VPN protocol. SSTP is a Transport Layer Security (TLS) based VPN protocol that uses HTTPS over the standard TCP port 443 to encapsulate and encrypt communication between the Always On VPN client and the RRAS VPN server. SSTP is a firewall-friendly protocol that ensures ubiquitous remote network connectivity. Although IKEv2 is the protocol of choice when the highest level of security is required for VPN connections, SSTP can still provide very good security when implementation best practices are followed.

SSTP Certificate

Since SSTP uses HTTPS for transport, a common SSL certificate must be installed in the Local Computer/Personal/Certificates store on the RRAS VPN server. The certificate must include the Server Authentication Enhanced Key Usage (EKU) at a minimum. Often SSL certificates include both the Server Authentication and Client Authentication EKUs, but the Client Authentication EKU is not strictly required. The subject name on the certificate, or at least one of the Subject Alternative Name entries, must match the public hostname used by VPN clients to connect to the VPN server. Multi-SAN (sometimes referred to as UC certificates) and wildcard certificates are supported.

Always On VPN Certificate Requirements for SSTP

Certification Authority

It is recommended that the SSL certificate used for SSTP be issued by a public Certification Authority (CA). Public CAs typically have their Certificate Revocation Lists (CRLs) hosted on robust, highly available infrastructure. This reduces the chance of failed VPN connection attempts caused by the CRL being offline or unreachable.

Using an SSL certificate issued by an internal, private CA is supported if the CRL for the internal PKI is publicly available.

Key Type

RSA is the most common key type used for SSL certificates. However, Elliptic Curve Cryptography (ECC) keys offer better security and performance, so it is recommended that the SSTP SSL certificate be created using an ECC key instead.

Always On VPN Certificate Requirements for SSTP

To use an ECC key, be sure to specify the use of a Cryptographic Next Generation (CNG) key and select the ECDSA_P256 Microsoft Software Key Storage Provider (CSP) (or greater) when creating the Certificate Signing Request (CSR) for the SSTP SSL certificate.

Always On VPN Certificate Requirements for SSTP

Most public CAs will support certificate signing using ECC and Elliptic Curve Digital Signature Algorithm (ECDSA). If yours does not, find a better CA. 😉

Forward Secrecy

Forward secrecy (sometimes referred to as perfect forward secrecy, or PFS) ensures that session keys can’t be compromised even if the server’s private key is compromised. Using forward secrecy for SSTP is crucial to ensuring the highest levels of security for VPN connections.

To enforce the use of forward secrecy, the TLS configuration on the VPN server should be prioritized to prefer cipher suites with Elliptic Curve Diffie-Hellman Ephemeral (ECDHE) key exchange.

Authenticated Encryption

Authenticated encryption (AE) and authenticated encryption with associated data (AEAD) is a form of encryption that provides better data protection and integrity compared to older block or stream ciphers such as CBC or RC4.

To enforce the use of authenticated encryption, the TLS configuration on the VPN server should be prioritized to prefer cipher suites that support Galois/Counter Mode (GCM) block ciphers.

Important Note: In Windows Server 2016, GCM ciphers can be used with both RSA and ECC certificates. However, in Windows Server 2012 R2 GCM ciphers can only be used when an ECC certificate is used.

SSL Offload

Offloading SSL to a load balancer or application delivery controller (ADC) can be enabled to improve scalability and performance for SSTP VPN connections. I will cover SSL offload for SSTP in detail in a future post.

Summary

SSTP can provide good security for VPN connections when implementation and security best practices are followed. For optimum security, use an SSL certificate with an EC key and optimize the TLS configuration to use forward secrecy and authenticated cipher suites.

Additional Information

Always On VPN ECDSA SSL Certificate Request for SSTP

Always On VPN and Windows Server Routing and Remote Access Service (RRAS)

Always On VPN Protocol Recommendations for Windows Server RRAS

Always On VPN Certificate Requirements for IKEv2

3 Important Advantages of Always On VPN over DirectAccess

Microsoft SSTP Specification on MSDN