Read Windows Server 2008 R2 Unleashed Online
Authors: Noel Morimoto
Windows Server 2008 R2 Unleashed (169 page)
ensure confidentiality: data encryption and data integrity. IPSec uses an authentication
header (AH) to provide source authentication and integrity without encryption and the
Encapsulating Security Payload (ESP) to provide authentication and integrity along with
encryption. With IPSec, only the sender and recipient know the security key. If the
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authentication data is valid, the recipient knows that the communication came from the
sender and that it was not changed in transit.
IP
UDP
L2TP
PPP
PPP
HEADER
HEADER
HEADER
HEADER
PAYLOAD
IPSEC
IP
UDP
L2TP
PPP
IPSEC
IPSEC
PPP
ESP
HEADER
HEADER
HEADER
HEADER
ESP
AUTH
PAYLOAD
HEADER
TRAILER
TRAILER
ENCRYPTED BY IPSEC
FIGURE 24.7
Structure and architecture of the IPSec packet.
NOTE
IPSec also plays a key role in another remote access technology, the new Windows
Server 2008 R2 DirectAccess.
DirectAccess in Windows Server 2008 R2
863
Secure Socket Tunneling Protocol
Introduced in Windows Server 2008, SSTP was specifically developed to get around the
difficulties of setting up VPN tunnels through corporate firewalls, which block many of
the ports and protocols used by PPTP and L2TP. The SSTP tunnel uses the HTTP over SSL
(HTTPS) protocol, which is widely supported for secure web traffic. SSTP uses port 443 for
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the connection.
The tunneling protocol functions by encapsulating the original IP packet with a PPP
header and then an SSTP header. The SSTP header, the PPP header, and the original IP
packet are all encrypted by the SSL session. Finally, an IP header is added to the packet
and it is routed to the destination. The structure of the packet is shown in Figure 24.8.
ENCRYPTED BY SSL
IP
TCP
SSTP
PPP
PPP
HEADER
HEADER
HEADER
HEADER
PAYLOAD
PPP FRAME
ptg
FIGURE 24.8
Structure and architecture of the SSTP packet.
NOTE
Interestingly, even though SSTP is based on the HTTPS web protocol, the VPN server
does not have to be configured with IIS. The RRAS VPN server listens for SSTP connec-
tions on the uniform resource identifier (URI) /sra_{BA195980-CD49-458b-9E23-
C84EE0ADCD75}/. This does not conflict with or require IIS, so IIS can be installed if
needed for other purposes.
Unfortunately, SSTP does not support tunneling through web proxies that require authen-
tication. Another limitation of SSTP is that it does not support site-to-site connections in
Windows Server 2008 R2, which both PPTP and L2TP do.
DirectAccess in Windows Server 2008 R2
DirectAccess is a new remote access protocol in Windows Server 2008 R2 that provides
network node connectivity to remote systems without any user login requirements.
DirectAccess addresses several challenges with traditional VPN, including the following:
. The need for the user to manually connect to the VPN.
. The delay the user experiences when connecting to the VPN while health checks are
completed during the connection process.
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Server-to-Client Remote Access and DirectAccess
. The need for the user to reconnect manually if an established VPN connection is lost.
. The slow performance when all traffic (intranet and Internet) is routed through the
VPN connection.
These challenges can cause users to limit the use of traditional VPN solutions. DirectAccess
has been designed from the ground up to address those challenges. DirectAccess hides all
the connection processes from the users and intelligently routes intranet versus Internet
traffic, thereby alleviating the challenges of traditional VPNs. It connects as soon as the
computer starts up and conducts the health checks, rather than when the user is logging
in. The connection process is transparent to the user and the user never needs to explicitly
connect to DirectAccess. Finally, DirectAccess has built-in options to control how DNS
requests are handled, effectively bifurcating the Internet and intranet traffic to avoid
burdening the remote access connection and improving performance.
DirectAccess creates an encrypted point-to-point tunnel from a remote user—in this case,
specifically a remote user on Windows 7—to the internal “enterprise” network. The differ-
ence is that the connection is transparent to the user. Once configured, the computer will
automatically connect to the office from any available Internet connection. The user expe-
rience is almost identical to being in the office. In addition, through the use of the
Windows Server 2008 R2 NPS server, remote-connected clients can be securely managed
similarly to internal client systems.
ptg
NOTE
Although positioned as an alternative to a VPN, the DirectAccess technology has all the
elements of a VPN. It establishes a secure private tunnel through public networks
using IPSec and certificates, with an end result functionally not much different from
L2TP. The differences are mainly administrative rather than technical.
DirectAccess uses IPv6, IPSec, and certificates to establish secure connections from the
DirectAccess clients to intranet resources via the DirectAccess server. To traverse public IPv4
networks, DirectAccess uses IPv6 transition technologies such as ISATAP, Teredo, and 6to4.
DirectAccess has some specific requirements, as follows:
. The server running Windows Server 2008 R2 needs to have two network cards: one
attached to the intranet and one attached to the Internet.
. The Internet network card must have two consecutive public IPv4 addresses.
. The Intranet resources and applications must support IPv6.
. The DirectAccess clients need to be running Windows 7; older clients are not
supported.
DirectAccess in Windows Server 2008 R2
865
. A domain controller and DNS server that the systems are connected to need to be
running Windows Server 2008 SP2 or Windows Server 2008 R2.
. A PKI needs to be available to issue certificates with a published Internet available
certificate revocation list (CRL).
These requirements are somewhat stringent and might prevent many organizations from
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deploying DirectAccess. However, for an organization with an up-to-date infrastructure,
servers, and clients, DirectAccess can be an excellent solution.
DirectAccess and IPv6
DirectAccess is designed on top of IPv6 and requires that all endpoint devices support
IPv6. It is one of the first services to require this modern protocol.
DirectAccess is most likely to be deployed in an IPv4 world, given the prevalence of IPv4
on the Internet today. This creates an IPv4 gap (shown in Figure 24.9) across which IPv6
devices like DirectAccess clients need to communicate.
?
IPv4 Network
?
ptg
Gap
IPv6 Device
IPv6 Device
FIGURE 24.9
The IPv4 gap between IPv6 devices.
Most organizations will need to use IPv6 transition technologies to bridge the IPv4 gap
from their IPv6 enlightened devices to communicate. This, in effect, routes the IPv6
communications through the IPv4 protocol stack, as shown in Figure 24.10. The packets
traveling down the IPv6 protocol stack take a sharp turn and move across the protocol
stack to the IPv4 protocol stack, allowing them to transit the IPv4 network. On the other
side, the same packets come in via the IPv4 protocol stack, but are routed to the IPv6 stack.
Application Layer
Application Layer
IPv4 Network
Transport Layer
Transport Layer
IPv4
IPv4
IPv6 Device
IPv6
IPv6
IPv6 Device
Network Layer
Network Layer
FIGURE 24.10
Bridging the IPv4 gap with transition technologies.
Communications between IPv6 devices like DirectAccess clients over IPv4 networks is
accomplished with IPv6 over IPv4 tunneling. In tunneling, the IPv6 packets are encapsu-
lated in an IPv4 packet by the source device and routed through the IPv4 network. When
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the encapsulated packet arrives at the boundary between the IPv4 and IPv6 networks, the
IPv4 encapsulation is stripped off and the IPv6 packet continues on its way. The most
common tunneling protocols are ISATAP, 6to4, and Teredo.
For organizations, the IPv6 tunneling protocols are used for the following purposes:
.
ISATAP—
This protocol is used to automatically assign IPv6 addresses within the
organization’s IPv4 intranet.
.
6to4—
This protocol is used to automatically assign IPv6 addresses and route across
the public IPv4 Internet.
.
Teredo—
This protocol is used to automatically assign IPv6 addresses and route
across the public IPv4 Internet to devices behind Network Address Translation (NAT)
firewalls.
For organizations that have not deployed IPv6 natively, Microsoft Windows Server 2008
R2 and Windows 7 support ISATAP, 6to4, and Teredo transition protocols. However, even
while DirectAccess clients are using IPv6 transitional technologies like Teredo or 6to4, it is
ultimately communicating from IPv6 clients to IPv6 hosts.
Internally, DirectAccess can use Network Address Translation-Protocol Translation (NAT-PT)
ptg
devices, which can be used to provide access to IPv4 resources. Resources that don’t support
IPv6 natively can be accessed through the use of a Network Address Translation-Protocol
Translation (NAT-PT) device. Microsoft Windows Server 2008 R2 does not currently include
that capability, so a third-party device would be needed for this functionality.
NOTE
NAT-PT is covered in IETF RFC-2766 (http://tools.ietf.org/html/rfc2766), but was
reclassified from a Proposed Standard to Historic due to issues with the standard.
RFC4966 (http://tools.ietf.org/html/rfc4966) contains the details of these issues.
These include difficulty with integrity mechanisms, inability to redirect protocols that
lack demultiplexing capabilities, premature state timeouts, loss of information due to
IPv4 and IPv6 header incompatibilities, packet fragmentation issues, and an inability to
handle multicast traffic. NAT-PT devices are only recommended as a stop-gap measure
due to these issues.
For organizations that have not deployed IPv6, the deployment of DirectAccess is an
excellent project to test the IPv6 waters with. The infrastructure can be deployed in paral-
lel with existing remote access solutions and without impacting the existing IPv4 address-
ing scheme, providing IT personnel with a chance to learn IPv6 and its integration with
IPv4 in a low-impact production setting.
See Chapter 10, “Domain Name System and IPv6,” for a detailed discussion of the IPv6
protocol and the transition technologies needed to bridge the IPv4 gap.
DirectAccess in Windows Server 2008 R2
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A Tale of Two Tunnels
The DirectAccess client establishes two tunnels, which are key to the versatility of this
method of remote access. These tunnels are IPSec Encapsulating Security Payload (ESP)
tunnels that are authenticated with certificates and encrypted to ensure the confidential-
ity. These tunnels are as follows:
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.
Computer tunnel—
The computer tunnel is established first when the DirectAccess
client starts up. This tunnel is authenticated with the computer certificate only and
provides access to the intranet DNS and domain controllers. This tunnel is also used
to download the computer group policy and request user authentication.
.
User tunnel—
This tunnel is authenticated with the computer certificate and the
user credentials and provides access to the intranet resources. This tunnel is used to
download user group policy as well.
Both these tunnels are established transparently to the user. The user does not have to
present credentials above and beyond the normal Windows logon to establish remote
access. The two tunnels are shown in Figure 24.11.
ptg
unnel
Computer T
DirectAccess
unnel
Client
User T
DirectAccess
Server
Internal Network
NLS
Certificate
Active Directory
Server
Server
Server
FIGURE 24.11
The two DirectAccess tunnels.
These tunnels allow for the transparent establishment of remote access, essentially allow-
ing the computer to connect to the intranet even when no user is logged on. This allows
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the DirectAccess client to receive Group Policy remotely and be managed by the manage-
ment servers in the intranet. When a user logs on, they are authenticating to the intranet
and, thus, ensuring that users are subject to the latest requirements, password changes,