Deployment Scenarios for Office 365 and AAD Identity

In my previous post from yesterday on understanding Office 365 and AAD federated identity types, I talked about the two methods for allowing our users to sign in to the Microsoft cloud services with our on-premises identity using either DirSync, AADSync or FIM for same sign-on or using ADFS for single sign-on. Now that we understand the products at a high-level, I want to cover off some options for deployment scenarios and specifically, how we can leverage Microsoft Azure to host these services.

Customers are increasingly trying to cut the cord with their on-premise datacenters due to the high cost of running them and are looking for cheaper alternatives to run their services. Moving our email, collaboration and communication productivity tools to Office 365 is one way that we can work towards achieving that however in consuming these Office 365 services, we remove the need for having our on-premises Exchange, SharePoint and Lync servers but we replace them with servers that are used to synchronise our identities to the cloud or provide the authentication tokens. If these servers go down it could actually have a more detremental effect than the loss of an on-premise Lync server so we need to pay close attention.

On-Premise Deployments

DirSync, AADSync and FIM for Same Sign-On

If you have opted for a same sign-on deployment then unless you have a specific need for FIM because you have a complex infrastructure or if you have already deployed FIM and want to leverage that existing investment you will be deploying DirSync or AADSync. DirSync is the incumbant tool and AADSync is its replacement although DirSync is still supported and will continue to be supported for a currently undefined period of time so if you have already deployed DirSync then you don’t need to rush out and upgrade your servers to AADSync.

AADSync On-Premise

None of these products, DirSync, AADSync or FIM support clustering or high availability which means you can deploy only one of them at a time. FIM can be sweet talked into working as a clustered product but the process is unsupported and documented by Damian Flynn at http://www.damianflynn.com/2012/10/11/fim-sync-server-2010r2-cluster-build/. If you want to provide high availability for these applications then you will need to look outside the operating system and look to your hypervisor, assuming you are deploying them as virtual machines.

For DirSync and AADSync, the easiest thing to do will be to have a disaster recovery plan and a build document for the installation so that if you’re server melts, you can deploy a new one from a VM template in short order. If you were extra paranoid, you could have a VM deployed with the DirSync or AADSync binaries on the server ready to install (but not installed) so that if you had a failure you could simply run through the installer following your build document and be up and running in about 15 to 30 minutes.

For FIM, you definately want a backup of this server because a) its not highly available and b) there are complex configurations going on here and tryring to re-create this from scratch as we would likely do with DirSync and AADSync wouldn’t be fun nor quick.

ADFS for Single Sign-On

As we know from my previous article, deploying ADFS is more involved and requires more moving parts howeer luckily, all of these parts can be clustered or load balanced accordingly. The exception to this is the DirSync or AADSync server that you deploy in addition to the ADFS servers to sync the users identities but not the password attribute to go with it.

ADFS On-Premise

ADFS Proxies which reside in your DMZ network segment are essentially web servers which can be load balanced. We only require Port 443 for HTTPS SSL pages to be made publicly accessible and we can use either Windows native NLB or we can use a hardware or software load balancer such as a Citrix Netscaler, KEMP Loadmaster or an A10 Thunder load balancer. As a side note of interest, Citrix and A10 both support integration into VMM so if you are using a Microsoft private cloud with Hyper-V and VMM in your on-premise network then these products can be easily integrated into your deployment approach for new servers.

ADFS servers live in your clean, corporate network and route requests between the proxies in your DMZ to the Active Directory domain controllers to retrieve the authorization for users. The ADFS servers use a Windows Internal Database (WID) as standard which supports farms of up to five ADFS servers however if you need more than five servers, you will need a seperate SQL Server for the database which we can of course cluster.

Azure Deployment

DirSync, AADSync and FIM for Same Sign-On

As I mentioned earlier, companies are interested in cord cutting the on-premise datacenter as we know so moving things into the cloud where it is possible and makes sense helps us to achieve this and more importantly, reduce the dependancy on our internal facilities. With DirSync, AADSync and FIM deployments for same sign-on, we can really easily achieve this with Microsoft Azure.

AADSync Azure

The components that make this design work are the Azure VPN which provides site-to-site connectivity between your on-premises environment and Microsoft Azure. Once you have the Azure VPN configured and working and you have your virtual network segments configured in Microsoft Azure, we need to deploy an Active Directory Domain Controller into Azure using an IaaS VM. This will hold a replica of your Active Directory database from on-premise. We then deploy the DirSync, AADSync or FIM server on an IaaS VM in Azure.

By deploying the synchronisation VM in Azure along with the domain controller, the two servers are within the same AD Site which you will have created for Azure and will allow the synchronisation server to contact AD for the user data it needs and will allow it very fast access to the Azure Active Directory service to sync your objects to the cloud directory.

For high availability in this design, we can deploy multiple Domain Controllers into the Azure AD Site and we can use the Azure VPN service in a point-to-multi-point configuration so that two of your on-premise datacenters have an endpoint for the Azure VPN so that we aren’t dependant on a single site for on-premise connectivity. Remember that with this same sign-on deployment, we can only have a single synchronisation server so it is not possible to make this element highly available. When we deploy multiple Active Directory Domain Controllers into Azure, we need to make sure that these VMs go into an Availability Set together which causes the Azure fabric to place these VMs on seperate hosts and racks in the environment so that they are not effected by maintenance operations.

ADFS for Single Sign-On

Using Azure to deploy our ADFS for single sign-on deployment really is the way to show case the power and ease at wihch we can deploy a complex solution with Microsoft Azure. The building block of this design is the same as that of the DirSync and AADSync in that we start out with configuring Azure VPN in a point-to-point or point-to-multi-point connection to our on-premise environment and we then deploy multiple Active Directory Domain Controllers which provide our authentication source.

ADFS Azure

In deploying SSO with ADFS, we need to configure, deploy and test the ADFS environment before we deploy and configure the DirSync or AADSync server. I must atest to not fully understanding the reason for this but Microsoft recommend it so we do it. As you would do for an on-premise deployment, we deploy two ADFS Proxies which recieve our incoming token requests and we deploy two ADFS Servers which do the back and forth between our ADFS Proxies and the AD Domain Controllers to authorize users.

As we did with our previous same sign-on design for a Microsoft Azure deployment, we need to make sure we place our IaaS VMs into Availability Sets however this time we have three sets: one for our Domain Controllers, one for the ADFS Proxies and one for the ADFS Servers.

With an on-premise deployment, we need to buy and configure a load-balancer to use with the multiple ADFS Proxy servers however in Azure we can simply use the Azure Load Balancer to quickly and easily achieve this.

With the ADFS for single sign-on deployment in Microsoft Azure, if having two VMs running for each service isn’t quite enough availability for you because you are concerned about the resiliency that Microsoft provide within a single Azure datacenter, you could take the deployment to another level and use two datacenters. Using two Microsoft Azure datacenters, we split the services provided by the deployment throughout the Azure environment and use the Azure Traffic Manager to provide Geolocation awareness for users and direct them to the most appropriate ADFS Proxy for authentication. If you are deploying ADFS for single sign-on in an organisation which has users throughout the globe then this could be an ideal deployment to achieve not only your high availability requirements for IT but also to improve the user experience by sending the user to the ADFS Proxy closest to them.

Cost Consideration

All of this talk of Azure deployments is very nice but we need to be aware of our costs. Deploying services on-premises has costs associated and these costs are often a lot higher than people realise because they don’t fully take into account every facet of the infrastructure. When you are costing up an on-premise VM you will likely include the cost of the SAN disk occupation or the percentage of a host it occupies and the host of that virtualization host but are you factoring in the amount of extra power that server will consume as a result of the extra CPU cycles or the fraction of load that adds to your UPS or your network switches?

Implementing a simple deployment of DirSync or AADSync will be very cheap and I would challenge any enterprise to be able to do it themselves cheaper. A single datacenter deployment of ADFS for single sign-on will cost more to implement than same sign-on due to the increased number of servers and the addition of the Azure Load Balancer however that cost will double if you extend that to a dual Azure datacenter deployment not to mention the increased configuration complexity.

To conclude, make sure you consider the cost and complexity of what you are proposing to implement and make sure that what you plan to do is really what you need to do. If all your users are based in the UK then having that all sining, dual datacenter, multi-point Azure VPN deployment split across the UK and East Coast US with Geolocation Traffic Management probably isn’t what you really need and you will be wasting resources in both money to pay for it and time and complexity to manage it.

Understanding Office 365 and AAD Federated Identity Types

Recently, I’ve undertaken a number of customer chalk and talk sessions on Office 365 to discuss with them some of the benifits they can expect to see from moving from on-premise services to Office 365 hybrid and cloud services. Amongst the myriad of topics that get covered in these sessions, one of the biggest areas for discussion and contention is identify federation from the on-premise environment to Office 365 which uses Azure Active Directory (AAD) as it’s identity management system.

I thought I would take this oppourtunity to cover off some of the high-level points of the trade-offs and differences between the ways of achieving identity federation with Office 365 and Azure Active Directory. Please remember that this isn’t an exhaustive list of things to consider but a good taster.

In some future posts, I will be covering deployment scenarios for the two methods of identity federation and also the software we need to configure and deploy in order to make it work.

What is Identity Federation

Simply put, identity federation is the means of allowing your users to logon to both on-premise services and Office 365 and Azure Active Directory authentication based services with a single identity, the identity they know and love that resides currently in your on-premise Active Directory and to most people is simply the username and password that they use to logon to your internal PCs and other systems.

Without identity federation, we have a scenario where users have split personas resulting in them having one logon for your on-premise services and another for their cloud services with Office 365 and Azure Active Directory. If you work in a highly secure, militry level environment, perhaps this is actually what you want and you don’t want to potentially expose your internal identies to the cloud but for 99% of people looking at Office 365, you want the simplified experience for your end-users of having just one credential to rule them all.

Single Sign-On vs. Same Sign-On

Single Sign-On and Same Sign-On are the same yet different. Single Sign-On refers to the ability to logon once such as to a domain joined Windows desktop PC and then not have to re-enter credentials for any of the services you consume during that session and this is the holy grail of integration scenarios where the user experience is totally seamless and the user doesn’t need to think about anything other than which app or product they want to work with next.

Same Sign-On refers to using a single identity, provided by our identity federation solution however instead of the user seamlessly being logged into these systems, the user may be prompted at various stages to re-enter their credentials in order to authenticate to a web service or an application such as with the Lync Client or a SharePoint team site.

Both of these scenarios are achievable with Office 365 and Azure Active Directory however in order to achieve one over the other increases the amount of work and effort required upfront in order to achieve success. I will explain in more detail further on the technical differences but for now, know that Same Sign-On is the easiest to implement and requires nothing more than one server to run the syncrohisation software. Single Sign-On requires more servers to be deployed and it requires some firewall reconfiguration in order to allow the services to be properly accessible.

Deciding Which Identity Type is Right for You

In this section, I will talk about some of the determining factors for deciding betwween same and single sign-on.

User Experience

The end-user experience is obviously high on the agenda when it comes to deciding between the two identity federation modes. Same sign-on means users can login to services with the same username and password whilst single sign-on allows users to seamlessly move between applications and services without the need to re-authenticate.

The winner here is clearly single sign-on however this comes with a caveat that Outlook does not behave in a truely singluar fashion like the other applications do.

Due to the way that Office 365 uses the RPC over HTTPS protocol with Basic Authentication, Outlook users will still be prompted to enter their credentials even when single sign-on is deployed and properly configured. This is a common misconception and people see it as a problem with their single sign-on configuration or deployment but sadly it is just the way that Outlook behaves. The workaround to this issue is for users to select the Remember My Credentials option and their password will be cached in the Windows Credential Manager until such a time that the user changes their password.

Password Security

Password security is in my opinion, the number one reason that people consider the single sign-on deployment over same sign-on.

With a same sign-on deployment, the authentication to Office 365 and Azure Active Directory service is performed within AAD. The syncronisation software that is run within your organisation syncs both the users and their passwords to the cloud AAD directory. When a user requests access to a service, the password entered by the user is sent to AAD for verification and authorization. All this means that there are copies of your passwords stored in AAD.

With single sign-on, your passwords are not stored in the cloud AAD directory but instead, only the usernames and a few other attributes of the users. When a user requests a login to a service, the authentication request is forwarded to servers within your organisation known as proxies which then forward the request to your internal Active Directory domain controllers. Once authorized, a token is sent back to Office 365 and Azure Active Directory to approve the login. In a nutshell, the passwords never leave your environment, only tokens approving or denying the connection.

The winner for password security is likely to be single sign-on. The idea of having passwords stored in the cloud is too much for some organisations whereas for others, the idea of the authentication tokens flying back and forth is equally bad coupled with the exposure a single sign-on solution potentially adds to your internal directory environment.

Password Changes

Users need to be able to change their passwords in accordance with your organisations security policy. Typically, in order for a user to make that change, they need to be either on-premise or connected to the on-premise environment via a VPN or such if they are working remotely. Windows Server DirectAccess helps with password changes amongst many other scenarios where the users need to be connected to the corporate network.

If you opt for a same sign-on implementation then by enabling the Password Write-Back feature in the sync application, we can enable users to change their passwords without requiring a connection back to the corporate environment. This password change can be performed via one of the Office 365 application websites such as Outlook Web App. Once the password is changed by the user, it is written to the cloud Azure Active Directory and is synchronised back to the corporate directory when the nextx synchronisation occurs.

If you deploy a single sign-on model then you do not have the flexibility of enabling users to perform password changes via the portals because there is no cloud storage of the password and the cloud environment is not aware of the users password but only that they were authenticated from your environment.

If you are looking for ways to reduce the user reliance on VPN technologies and enable them to do more of their work remotely using cloud based applications then same sign-on could provide an added benifit here. Companies which use single sign-on will need to maintain these VPN technologies even if simply to allow users to change their passwords as required. As I have mentioned previously, DirectAccess if not already deployed could be a real answer here as it provides always-on connectivity back to the corporate environment and does not require the user to interact with a VPN client improving the user experience.

Access Revokation

In a scenario where you need to revoke somebodies access very quickly either due to a confidentiality issue or an employee has gone rogue, single sign-on is the clear winner. Same sign-on works by syncronising the stage of user objects periodically based on a scheduled job from on-premise to the Azure Active Directory. If a user account is disabled on-premise then it could take sometime for that change to make it’s way to the AAD directory and further damage could be done in the scenario as a result.

If you are using single sign-on, when a user account is disabled, that user account will no longer be able to authenticate to Office 365 and AAD federated applications as soon as the account is disabled because those services will no longer be able to authorize that user based on the fact that, that authentication request is sent directly into your environment.

Availability and Reliability

This point is closely linked to the password security requirement, as is configuration complexity. In order for users to be able to sign-in to Office 365 and AAD linked services, there needs to be an authentication service available to process the request. For same sign-on where the passwords are stored in the cloud directory, the availability and reliability is provided by Microsoft Azure.

As we understand from the Microsoft Azure SLA page at http://azure.microsoft.com/en-gb/support/legal/sla/ Azure Active Directory Free provides no guarantee of uptime or SLA although through my personal experience and use of it, I have never seen a problem with it being available and working. Azure Active Directory Basic and Premium both offer a 99.9% enterprise SLA along with a slew of other features but at a cost.

For deployments using single sign-on, because the authentication requests are redireted to servers which are maintained by you as the customer, the availability and reliability of the authentication service is dependant on you and is born of a number of factors: we have authentication proxies, authentication servers and domain controllers all of which need to be available for the solution to work and not to mention any firewalls, load balancers, networks and internet connections, service providers, power sources, you name it, all of which are consumed by these servers.

I’ll be covering some deployment scenarios for both same and single sign-on in a future post however for now, we’ll assume all of this resides in your on-premise datacenters. If you have reliable on-premise servers and infrastructure services and you can provide a highly available solution for single sign-on then you will have no problems however if any of the components in the single sign-on server chain fail, users will be unable to authenticate to Office 365 or AAD federated applications which will cause a user experience and an IT support issue for you.

Configuration Complexity

Taking what we learn from the reliability and availability information above, it is fairly apparent that there are more moving parts and complexities to the single sign-on implementation. If you as an organisation are looking to reduce your configuration complexity because you want to unlock time from your internal IT resources or you are looking to improve your uptimes to provide a higher level of user satisfaction then you should consider whether the complexity of a single sign-on implemention is right for you? In theory, once the solution is deployed it should be no hassle at all but all know that servers go bad from time to time and even when things are working right there is still things to contend with like software updates, security patching, backups and so forth.

The same sign-on implemention requires only one server to implement, requires no firewall changes to allow inbound traffic to your network (all communication is based on an outbound connection from the server) and if you wanted to, you could even omit the backups because the installation of the software is very simple and can be recovered from scratch is little time at all.

Same sign-on is definately the winner in the complexity category so if you have a small or over-worked IT department then this could be an assist in the war against time spent on support issues however single sign-on clearly provides a richer user experience so it needs to be a balanced debate about the benifits of avoiding the configuration complexity.

Software Implementation

In this section I am going to quickly cover off the software we use for these scenarios but I am not going to go into configuration of them or the deployment scenarios as I want to save that for another post at the risk of this post dragging on too long. The other reason I want to cover these here is that throughout this post I have talked of same sign-on and single sign-on but I want to translate that into a software term for later reference.

Same Sign-On using DirSync, AADSync or FIM

Same sign-on is implemented using the Directory Synchronisation (DirSync), the Azure Active Directory Sync (AADSync) tools or using Forefront Identity Manager with the Azure AD Connector.

The DirSync tool has been around for quite some time now and has been improved with new features from one iteration to the next. For example, initial versions of DirSync didn’t support Password Sync to the cloud environment which meant users had different passwords for on-premise and cloud which was a reason a lot of early Office 365 adopters didn’t adopt DirSync. With more recent additions to DirSync to support Password Sync and Write Back from the AAD cloud environment, DirSync has become a lot more popular and I find that the majority of customers seeking a fast track adoption of Office 365 going for DirSync. DirSync has a limitation of only working for environments with a single Active Directory forest which made it a non-starter for customers with more complex internal environments.

Forefront Identity Manager (FIM) with the Azure AD Connector is DirSync on steroids or rather, DirSync is a watered down version of FIM. DirSync is a pre-packaged and pre-configured version of FIM. Using the full FIM application instead of DirSync enables support for multi-forest environments and also for environments where identity sources include non-Active Directory environmnets such as LDAP or SQL based authentication sources. For customers wanting a same sign-on experience but with a complex identity solution internally, FIM was the only option. If you have FIM deployed in your environment already then you may want to take this route in order to help you sweat the asset.

AADSync is a relatively new tool and only came out of beta in September 2014. The AADSync tool is designed to replace DirSync as it provides additional features and functionality over DirSync for example, AADSync has support for multi-forest environments (although still only Active Directory based) making it much more viable for larger, complex customer environments. It also allows customers to control which attributes and user properties are synchronised to the cloud environment making it better for the more security concious amongst us.

Single Sign-On using ADFS

Single sign-on is implemented using Active Directory Federation Services (ADFS). ADFS is deployed in many different configurations according to the requirements of the organisation but in it’s simplest form, it requires an ADFS Proxy which is a server residing in your DMZ responsible for accepting the incoming request for authorization from Office 365 and AAD to your environment. This is passed to an ADFS Server which resides on the internal network and communicates with the Active Directory environment to perform the actual authorization.

There is an additional component in the mix and that is the requirement for either a DirSync or an AADSync server however this is deployed to push the user objects into AAD however there is no password sync or write back of attributes occuring here, this server is there just to allow AAD to know what users you have so that AAD knows whether a valid username has been entered in order to pass it down to your environment for authorization.

Because of the public nature of ADFS, it requires you to have public IP addresses available, certificates for the URLs used by ADFS and also requires you to have a DMZ segment exposed to the internet.

Deployment Scenarios

In a future post which I hope won’t take me too long to make available, I will talk about some of the deployment scenarios and options for deploying both same sign-on and also single sign-on. I will also cover how the release of AADSync effects existing deployments of DirSync or FIM.