VMware THINAPP 4.6 - MIGRATING APPLICATIONS TECHNICAL NOTE Specifications

VMware View Architecture Planning
View 4.6
View Manager 4.6
View Composer 2.6
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VMware View Architecture Planning
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Contents
VMware View Architecture Planning
5
1 Introduction to VMware View 7
Advantages of Using VMware View 7
VMware View Features 9
How the VMware View Components Fit Together 9
Integrating and Customizing VMware View 13
2 Planning a Rich User Experience 15
Feature Support Matrix 15
Choosing a Display Protocol 17
Benefits of Using View Desktops in Local Mode 18
Accessing USB Devices Connected to a Local Computer 20
Printing from a View Desktop 20
Streaming Multimedia to a View Desktop 21
Using Single Sign-On for Logging In to a View Desktop 21
Using Multiple Monitors with a View Desktop 21
3 Managing Desktop Pools from a Central Location 23
Advantages of Desktop Pools 23
Reducing and Managing Storage Requirements 24
Application Provisioning 25
Using Active Directory GPOs to Manage Users and Desktops 27
4 Architecture Design Elements and Planning Guidelines 29
Virtual Machine Requirements 29
VMware View ESX Node 34
Desktop Pools for Specific Types of Workers 35
Desktop Virtual Machine Configuration 38
vCenter and View Composer Virtual Machine Configuration and Desktop Pool Maximums 40
View Connection Server Maximums and Virtual Machine Configuration 40
View Transfer Server Virtual Machine Configuration and Storage 41
vSphere Clusters 42
VMware View Building Blocks 43
VMware View Pod 46
5 Planning for Security Features 49
Understanding Client Connections 49
Choosing a User Authentication Method 52
Restricting View Desktop Access 55
Using Group Policy Settings to Secure View Desktops
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Implementing Best Practices to Secure Client Systems 56
Assigning Administrator Roles 56
Preparing to Use a Security Server 57
Understanding VMware View Communications Protocols 61
6 Overview of Steps to Setting Up a VMware View Environment 67
Index 69
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VMware View Architecture Planning
VMware View Architecture Planning provides an introduction to VMware View™, including a description of its
major features and deployment options and an overview of how VMware View components are typically set
up in a production environment.
This guide answers the following questions:
n
Does VMware View solve the problems you need it to solve?
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Would it be feasible and cost-effective to implement a VMware View solution in your enterprise?
To help you protect your VMware View installation, the guide also provides a discussion of security features.
Intended Audience
This information is intended for IT decision makers, architects, administrators, and others who need to
familiarize themselves with the components and capabilities of VMware View. With this information,
architects and planners can determine whether VMware View satisfies the requirements of their enterprise for
efficiently and securely delivering Windows desktops and applications to their end users. The example
architecture helps planners understand the hardware requirements and setup effort required for a large-scale
VMware View deployment.
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Introduction to VMware View
1
With VMware View, IT departments can run virtual desktops in the datacenter and deliver desktops to
employees as a managed service. End users gain a familiar, personalized environment that they can access
from any number of devices anywhere throughout the enterprise or from home. Administrators gain
centralized control, efficiency, and security by having desktop data in the datacenter.
This chapter includes the following topics:
n
“Advantages of Using VMware View,” on page 7
n
“VMware View Features,” on page 9
n
“How the VMware View Components Fit Together,” on page 9
n
“Integrating and Customizing VMware View,” on page 13
Advantages of Using VMware View
When you manage enterprise desktops with VMware View, the benefits include increased reliability, security,
hardware independence, and convenience.
Reliability and Security
Virtual desktops can be centralized by integrating with VMware vSphere and virtualizing server, storage, and
networking resources. Placing desktop operating systems and applications on a server in the datacenter
provides the following advantages:
n
Access to data can easily be restricted. Sensitive data can be prevented from being copied onto a remote
employee's home computer.
n
Data backups can be scheduled without considering when end users' systems might be turned off.
n
Virtual desktops that are hosted in a datacenter experience little or no downtime. Virtual machines can
reside on high-availability clusters of VMware servers.
Virtual desktops can also connect to back-end physical systems and Windows Terminal Services servers.
Convenience
The unified management console is built for scalability on Adobe Flex, so that even the largest View
deployments can be efficiently managed from a single View Manager interface. Wizards and dashboards
enhance the workflow and facilitate drilling down to see details or change settings. Figure 1-1 provides an
example of the browser-based user interface for View Administrator.
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Figure 1-1. Administrative Console for View Manager Showing the Dashboard View
Another feature that increases convenience is the VMware remote display protocol PCoIP. PCoIP (PC-overIP) display protocol delivers an end-user experience equal to the current experience of using a physical PC:
n
On LANs, the display is faster and smoother than traditional remote displays.
n
On WANs, the display protocol can compensate for an increase in latency or a reduction in bandwidth,
ensuring that end users can remain productive regardless of network conditions.
Manageability
Provisioning desktops for end users is a quick process. No one is required to install applications one by one
on each end user's physical PC. End users connect to a virtual desktop complete with applications. End users
can access their same virtual desktop from various devices at various locations.
Using VMware vSphere to host virtual desktops provides the following benefits:
n
Administration tasks and management chores are reduced. Administrators can patch and upgrade
applications and operating systems without touching a user's physical PC.
n
Storage management is simplified. Using VMware vSphere, you can virtualize volumes and file systems
to avoid managing separate storage devices.
Hardware Independence
Virtual machines are hardware-independent. Because a View desktop runs on a server in the datacenter and
is only accessed from a client device, a View desktop can use operating systems that might not be compatible
with the hardware of the client device.
For example, although Windows Vista can run only on Vista-enabled PCs, you can install Windows Vista in
a virtual machine and use that virtual machine on a PC that is not Vista-enabled. Virtual desktops run on PCs,
Macs, thin clients, and PCs that have been repurposed as thin clients.
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Chapter 1 Introduction to VMware View
VMware View Features
Features included in VMware View support usability, security, centralized control, and scalability.
The following features provide a familiar experience for the end user:
n
Print from a virtual desktop to any local or networked printer that is defined on the client device, or use
the location-based printing feature to map to printers that are physically near the client system. The virtual
printer feature solves compatibility issues and does not require you to install additional print drivers in
a virtual machine.
n
Use multiple monitors. With PCoIP multiple-monitor support, you can adjust the display resolution and
rotation separately for each monitor.
n
Access USB devices and other peripherals that are connected to the local device that displays your virtual
desktop.
VMware View offers the following security features, among others:
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Use RSA SecurID two-factor authentication or smart cards to log in.
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Use SSL tunneling to ensure that all connections are completely encrypted.
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Use VMware High Availability to host desktops and to ensure automatic failover.
The following features provide centralized administration and management:
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Use Microsoft Active Directory to manage access to virtual desktops and to manage policies.
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Use the Web-based administrative console to manage virtual desktops from any location.
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Use a template, or master image, to quickly create and provision pools of desktops.
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Send updates and patches to virtual desktops without affecting user settings, data, or preferences.
Scalability features depend on the VMware virtualization platform to manage both desktops and servers:
n
Integrate with VMware vSphere to achieve cost-effective densities, high levels of availability, and
advanced resource allocation control for your virtual desktops.
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Configure View Connection Server to broker connections between end users and the virtual desktops that
they are authorized to access.
n
Use View Composer to quickly create desktop images that share virtual disks with a master image. Using
linked clones in this way conserves disk space and simplifies the management of patches and updates to
the operating system.
How the VMware View Components Fit Together
End users start View Client to log in to View Connection Server. This server, which integrates with Windows
Active Directory, provides access to a virtual desktop hosted on a VMware ESX server, a blade or physical PC,
or a Windows Terminal Services server.
Figure 1-2 shows the relationship between the major components of a VMware View deployment.
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Figure 1-2. High-Level Example of a VMware View Environment
Windows
View Client
Microsoft
Active Directory
Windows View Client
with Local Mode
View
Transfer Server
Mac
View Client
View
Administrator
(browser)
Thin Client
network
ThinApp
View
Connection
Server
non-vCenter VMs
VM
VMware vCenter Server
with View Composer
physical PCs
blade PCs
View Agent
ESX hosts running
Virtual Desktop virtual machines
Terminal Servers
virtual desktops
desktop OS
app
app
app
VM
VM
VM
VM
VM
VM
ESX host
View Agent
virtual machine
Client Devices
A major advantage of using VMware View is that desktops follow the end user regardless of device or location.
Users can access their personalized virtual desktop from a company laptop, their home PC, a thin client device,
or a Mac.
From Mac and Windows laptops and PCs, end users open View Client to display their View desktop. Thin
client devices use View thin client software and can be configured so that the only application that users can
launch directly on the device is View Thin Client. Repurposing a legacy PC into a thin client desktop can extend
the life of the hardware by three to five years. For example, by using VMware View on a thin desktop, you can
use a newer operating system such as Windows Vista on older desktop hardware.
View Connection Server
This software service acts as a broker for client connections. View Connection Server authenticates users
through Windows Active Directory and directs the request to the appropriate virtual machine, physical or
blade PC, or Windows Terminal Services server.
View Connection Server provides the following management capabilities:
10
n
Authenticating users
n
Entitling users to specific desktops and pools
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Chapter 1 Introduction to VMware View
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Assigning applications packaged with VMware ThinApp to specific desktops and pools
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Managing local and remote desktop sessions
n
Establishing secure connections between users and desktops
n
Enabling single sign-on
n
Setting and applying policies
Inside the corporate firewall, you install and configure a group of two or more View Connection Server
instances. Their configuration data is stored in an embedded LDAP directory and is replicated among members
of the group.
Outside the corporate firewall, in the DMZ, you can install and configure View Connection Server as a security
server. Security servers in the DMZ communicate with View Connection Servers inside the corporate firewall.
Security servers ensure that the only remote desktop traffic that can enter the corporate data center is traffic
on behalf of a strongly authenticated user. Users can access only the desktop resources that they are authorized
to access.
Security servers offer a subset of functionality and are not required to be in an Active Directory domain. You
install View Connection Server in a Windows Server 2008 server, preferably on a VMware virtual machine.
View Client
The client software for accessing View desktops runs either on a Windows or Mac PC as a native application
or on a thin client if you have View Client for Linux.
After logging in, users select from a list of virtual desktops that they are authorized to use. Authorization can
require Active Directory credentials, a UPN, a smart card PIN, or an RSA SecurID token.
An administrator can configure View Client to allow end users to select a display protocol. Protocols include
PCoIP, Microsoft RDP, and HP RGS for View desktops that are hosted on HP Blades. The speed and display
quality of PCoIP rival that of a physical PC.
View Client with Local Mode (formerly called Offline Desktop) is a version of View Client that has been
extended to allow end users to download virtual machines and use them on their local systems regardless of
whether they have a network connection.
Features differ according to which View Client you use. This guide focuses on View Client for Windows and
View Client for Mac. The following types of clients are not described in detail in this guide:
n
View Client for Linux, available only through certified partners.
n
Various third-party clients, available only through certified partners.
n
View Open Client, which supports the VMware partner certification program. View Open Client is not
an official View client and is not supported as such.
View Portal
From a Windows PC or laptop, end users can open a Web browser and use View Portal to download, install,
update, and start the Windows-based View Client. As of View 4.5, View Portal installs the full View Client for
Windows, with or without Local Mode.
To use View Portal, end users open an Internet Explorer browser and enter the URL of a View Connection
Server instance. View Portal provides a link for downloading the installer for the full View Client for Windows.
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View Agent
You install the View Agent service on all virtual machines, physical systems, and Terminal Service servers that
you use as sources for View desktops. This agent communicates with View Client to provide features such as
connection monitoring, virtual printing, and access to locally connected USB devices.
If the desktop source is a virtual machine, you first install the View Agent service on that virtual machine and
then use the virtual machine as a template or as a parent of linked clones. When you create a pool from this
virtual machine, the agent is automatically installed on every virtual desktop.
You can install the agent with an option for single sign-on. With single sign-on, users are prompted to log in
only when they connect to View Connection Server and are not prompted a second time to connect to a virtual
desktop.
View Administrator
This Web-based application allows administrators to configure View Connection Server, deploy and manage
View desktops, control user authentication, and troubleshoot end user issues.
When you install a View Connection Server instance, the View Administrator application is also installed. This
application allows administrators to manage View Connection Server instances from anywhere without having
to install an application on their local computer.
View Composer
You install this software service on a vCenter Server instance that manages virtual machines. View Composer
can then create a pool of linked clones from a specified parent virtual machine. This strategy reduces storage
costs by up to 90 percent.
Each linked clone acts like an independent desktop, with a unique host name and IP address, yet the linked
clone requires significantly less storage because it shares a base image with the parent.
Because linked-clone desktop pools share a base image, you can quickly deploy updates and patches by
updating only the parent virtual machine. End users' settings, data, and applications are not affected. As of
View 4.5, you can also use linked-clone technology for View desktops that you download and check out to use
on local systems.
vCenter Server
This service acts as a central administrator for VMware ESX servers that are connected on a network. vCenter
Server, formerly called VMware VirtualCenter, provides the central point for configuring, provisioning, and
managing virtual machines in the datacenter.
In addition to using these virtual machines as sources for View desktop pools, you can use virtual machines
to host the server components of VMware View, including Connection Server instances, Active Directory
servers, and vCenter Server instances.
You can install View Composer on the same server as vCenter Server to create linked-clone desktop pools.
vCenter Server then manages the assignment of the virtual machines to physical servers and storage and
manages the assignment of CPU and memory resources to virtual machines.
You install vCenter Server in a Windows Server 2003 or 2008 server, preferably on a VMware virtual machine.
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Chapter 1 Introduction to VMware View
View Transfer Server
This software manages and streamlines data transfers between the datacenter and View desktops that are
checked out for use on end users' local systems. View Transfer Server is required to support desktops that run
View Client with Local Mode (formerly called Offline Desktop).
Several operations use View Transfer Server to send data between the View desktop in vCenter Server and the
corresponding local desktop on the client system.
n
When a user checks in or checks out a desktop, View Manager authorizes and manages the operation.
View Transfer Server transfers the files between the datacenter and the local desktop.
n
View Transfer Server synchronizes local desktops with the corresponding desktops in the datacenter by
replicating user-generated changes to the datacenter.
Replications occur at intervals that you specify in local-mode policies. You can also initiate replications in
View Administrator. You can set a policy that allows users to initiate replications from their local desktops.
n
View Transfer Server distributes common system data from the datacenter to local clients. View Transfer
Server downloads View Composer base images from the Transfer Server repository to local desktops.
Integrating and Customizing VMware View
To enhance the effectiveness of VMware View in your organization, you can use several interfaces to integrate
VMware View with external applications or to create administration scripts that you can run from the
command line or in batch mode.
Integrating View with Business Intelligence Software
You can configure VMware View to record events to a Microsoft SQL Server or Oracle database.
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End-user actions such as logging in and starting a desktop session.
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Administrator actions such as adding entitlements and creating desktop pools.
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Alerts that report system failures and errors.
n
Statistical sampling such as recording the maximum number of users over a 24-hour period.
You can use business intelligence reporting engines such as Crystal Reports, IBM Cognos, MicroStrategy 9,
and Oracle Enterprise Performance Management System to access and analyze the event database.
For more information, see the VMware View Integration document.
Using View PowerCLI to Create Administration Scripts
Windows PowerShell is a command-line and scripting environment that is designed for Microsoft Windows.
PowerShell uses the .NET object model and provides administrators with management and automation
capabilities. As with any other console environment, you work with PowerShell by running commands, which
are called cmdlets in PowerShell.
The View PowerCLI provides an easy-to-use PowerShell interface to VMware View. You can use the
View PowerCLI cmdlets to perform various administration tasks on View components.
n
Create and update desktop pools.
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Add datacenter resources to a full virtual machine or linked-clone pool.
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Perform rebalance, refresh, or recompose operations on linked-clone desktops.
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Sample the usage of specific desktops or desktop pools over time.
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Query the event database.
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Query the state of View services.
You can use the cmdlets in conjunction with the vSphere PowerCLI cmdlets, which provide an administrative
interface to the VMware vSphere product.
For more information, see the VMware View Integration document.
Modifying LDAP Configuration Data in View
When you use View Administrator to modify the configuration of VMware View, the appropriate LDAP data
in the repository is updated. VMware View stores its configuration information in an LDAP compatible
repository. For example, if you add a desktop pool, VMware View stores information about users, user groups,
and entitlements in LDAP.
You can use VMware and Microsoft command tools to export and import LDAP configuration data in LDAP
Data Interchange Format (LDIF) files from and into VMware View. These commands are for advanced
administrators who want to use scripts to update configuration data without using View Administrator or
View PowerCLI.
You can use LDIF files to perform a number of tasks.
n
Transfer configuration data between View Connection Server instances.
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Define a large number of View objects, such as desktop pools, and add these to your View Connection
Server instances without using View Administrator or View PowerCLI.
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Back up your View configuration so that you can restore the state of a View Connection Server instance.
For more information, see the VMware View Integration document.
Using SCOM to Monitor View Components
You can use Microsoft System Center Operations Manager (SCOM) to monitor the state and performance of
VMware View components, including View Connection Server instances and security servers and View
services running on these hosts.
For more information, see the VMware View Integration document.
Using the vdmadmin Command to Administer View
You can use the vdmadmin command line interface to perform a variety of administration tasks on a View
Connection Server instance. You can use vdmadmin to perform administration tasks that are not possible from
within the View Administrator user interface or that need to run automatically from scripts.
For more information, see the VMware View Administration document.
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Planning a Rich User Experience
2
VMware View provides the familiar, personalized desktop environment that end users expect. End users can
access USB and other devices connected to their local computer, send documents to any printer that their local
computer can detect, authenticate with smart cards, and use multiple display monitors.
VMware View includes many features that you might want to make available to your end users. Before you
decide which features to use, you must understand the limitations and restrictions of each feature.
This chapter includes the following topics:
n
“Feature Support Matrix,” on page 15
n
“Choosing a Display Protocol,” on page 17
n
“Benefits of Using View Desktops in Local Mode,” on page 18
n
“Accessing USB Devices Connected to a Local Computer,” on page 20
n
“Printing from a View Desktop,” on page 20
n
“Streaming Multimedia to a View Desktop,” on page 21
n
“Using Single Sign-On for Logging In to a View Desktop,” on page 21
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“Using Multiple Monitors with a View Desktop,” on page 21
Feature Support Matrix
Most features, such as access to local USB devices, virtual printing, Wyse multimedia redirection (MMR), and
PCoIP and Microsoft RDP display protocols, are supported on most Windows client operating systems. You
must also take into consideration whether the feature is supported on the View desktop operating system.
When planning which display protocol and features to make available to your end users, use the following
tables to determine which client operating systems and agent (View desktop) operating systems support the
feature.
Editions of Windows Vista include Windows Vista Home, Enterprise, Ultimate, and Business. Editions of
Windows 7 include Home, Professional, Enterprise, and Ultimate. For Windows Terminal Server, the edition
is Standard Edition.
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Table 2-1. Features Supported on Operating Systems for View Desktops (Where View Agent Is Installed)
Windows
2003/2003 R2
Terminal Server
SP2, 32-bit
Windows 2008
SP2/2008 R2
Terminal Server 64bit
X
X
X
X
X
X
X
N/A
N/A
X
X
X
X
X
Multiple
monitors
X
X
X
Local Mode
X
X
X
Feature
Windows XP
Home/Pro
SP3, 32-bit
Windows Vista
SP1, SP2, 32-bit
Windows 7, 32bit and 64-bit
USB access
X
X
X
RDP display
protocol
X
X
X
PCoIP display
protocol
X
X
X
HP RGS display
protocol
X
X
Wyse MMR
X
X
Virtual printing
X
X
X
Smart cards
X
X
RSA SecurID
X
Single sign-on
With RDP 7
Table 2-2. Features Supported on Windows Clients
Feature
Windows XP Home/Pro
SP3, 32-bit
Windows Vista SP1, SP2,
32-bit
Windows 7, 32-bit and 64-bit
USB access
X
X
X
RDP display protocol
X
X
X
PCoIP display protocol
X
X
X
HP RGS display protocol
X
X
Wyse MMR
X
X
Virtual printing
X
X
X
Smart cards
X
X
X
RSA SecurID
X
X
X
Single sign-on
X
X
X
Multiple monitors
X
X
X
Local Mode
X
X
X
Table 2-3. Features Supported on Mac Clients
Feature
Mac OS X (10.5,6)
Mac OS X (10.6)
X
X
USB access
RDP display protocol
PCoIP display protocol
HP RGS display protocol
Wyse MMR
Virtual printing
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Chapter 2 Planning a Rich User Experience
Table 2-3. Features Supported on Mac Clients (Continued)
Feature
Mac OS X (10.5,6)
Mac OS X (10.6)
RSA SecurID
X
X
Single sign-on
X
X
Smart cards
Multiple monitors
Local Mode
In addition, several VMware partners offer thin client devices for VMware View deployments. The features
that are available for each thin client device are determined by the vendor and model and the configuration
that an enterprise chooses to use. For information about the vendors and models for thin client devices, see
the Thin Client Compatibility Guide, available on the VMware Web site.
Choosing a Display Protocol
A display protocol provides end users with a graphical interface to a View desktop that resides in the
datacenter. You can use Microsoft RDP (Remote Desktop Protocol), HP RGS for HP physical machines, or
PCoIP (PC-over-IP).
You can set policies to control which protocol is used or to allow end users to choose the protocol when they
log in to a desktop.
NOTE When you check out a desktop for use on a local client system, neither of the RDP or PCoIP remote
display protocols is used.
VMware View with PCoIP
PCoIP is a new high-performance remote display protocol provided by VMware. This protocol is available for
View desktops that are sourced from virtual machines, Teradici clients, and physical machines that have
Teradici-enabled host cards.
PCoIP can compensate for an increase in latency or a reduction in bandwidth, to ensure that end users can
remain productive regardless of network conditions. PCoIP is optimized for delivery of images, audio, and
video content for a wide range of users on the LAN or across the WAN. PCoIP provides the following features:
n
You can use up to 4 monitors and adjust the resolution for each monitor separately, up to 2560 x 1600
resolution per display.
n
You can copy and paste text between the local system and the View desktop, but you cannot copy and
paste system objects such as folders and files between systems.
n
PCoIP supports 32-bit color.
n
PCoIP supports 128-bit encryption.
n
PCoIP supports Advanced Encryption Standard (AES) encryption, which is turned on by default.
n
For users outside the corporate firewall, you can use this protocol with your company's virtual private
network or with View security servers.
Client hardware requirements include the following:
n
800MHz or higher processor speed
n
x86-based processor with SSE2 extensions
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Microsoft RDP
Remote Desktop Protocol is the same protocol many people already use to access their work computer from
their home computer. RDP provides access to all the applications, files, and network resources on a remote
computer.
Microsoft RDP provides the following features:
n
You can use multiple monitors in span mode.
n
You can copy and paste text between the local system and the View desktop, but you cannot copy and
paste system objects such as folders and files between systems.
n
You can configure the amount of bandwidth used by Adobe Flash content to improve the overall Web
browsing experience and make other applications more responsive.
n
RDP supports 32-bit color.
n
RDP supports 128-bit encryption.
n
You can use this protocol for making secure, encrypted connections to a View security server in the
corporate DMZ.
HP RGS Protocol
RGS is a display protocol from HP that allows users to access the desktop of a remote physical computer over
a standard network.
You can use HP RGS as the display protocol when connecting HP Blade PCs, HP Workstations, and HP Blade
Workstations. Connections to virtual machines that run on VMware ESX servers are not supported.
HP RGS provides the following features:
n
You can use multiple monitors in span mode.
n
You can configure the amount of bandwidth used by Adobe Flash content to improve the overall Web
browsing experience and make other applications more responsive.
VMware does not bundle or license HP RGS with VMware View. Contact HP to license a copy of HP RGS
version 5.2.5 to use with VMware View. For information about how to install and configure HP RGS
components, see the HP RGS documentation available at http://www.hp.com.
Benefits of Using View Desktops in Local Mode
With View Client with Local Mode, users can check out and download a View desktop to a local system such
as a laptop. Administrators can manage these local View desktops by setting policies for the frequency of
backups and contact with the server, access to USB devices, and permission to check in desktops.
For employees at remote offices with poor network connections, applications run faster on a local View desktop
than on a remote desktop. Also, users can use the local version of the desktop with or without a network
connection.
If a network connection is present on the client system, the desktop that is checked out continues to
communicate with View Connection Server to provide policy updates, and ensure that locally cached
authentication criteria is current. By default, contact is attempted every 5 minutes.
View Client with Local Mode is the fully supported feature that in earlier releases was an experimental feature
called View Client with Offline Desktop.
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Chapter 2 Planning a Rich User Experience
View desktops in local mode behave in the same way as their remote desktop equivalents, yet can take
advantage of local resources. Latency is eliminated, and performance is enhanced. Users can disconnect from
their local View desktop and log in again without connecting to the View Connection Server. After network
access is restored, or when the user is ready, the checked-out virtual machine can be backed up, rolled back,
or checked in.
Local resource
utilization
After a local desktop is checked out, it can take advantage of the memory and
CPU capabilities of the local system. For example, memory available beyond
what is required for the host and guest operating systems is usually split
between the host and the local View desktop, regardless of the memory settings
that are specified for the virtual machine in vCenter Server. Similarly, the local
View desktop can automatically use up to two CPUs available on the local
system, and you can configure the local desktop to use up to four CPUs.
Although a local desktop can take advantage of local resources, a Windows 7
or Windows Vista View desktop that is created on an ESX 3.5 host cannot
produce 3-D and Windows Aero effects. This limitation applies even when the
desktop is checked out for local use on a Windows 7 or Windows Vista host.
Windows Aero and 3-D effects are available only if the View desktop is created
using vSphere 4.x.
Conserving datacenter
resources by requiring
local mode
You can reduce datacenter costs associated with bandwidth, memory, and CPU
resources by requiring that View desktops be downloaded and used only in
local mode. This strategy is sometimes called a bring-your-own-PC program
for employees and contractors.
Check-outs
When the View desktop is checked out, a snapshot is taken in vCenter, to
preserve the state of the virtual machine. The vCenter Server version of the
desktop is locked so that no other users can access it. When a View desktop is
locked, vCenter Server operations are disabled, including operations such as
powering on the online desktop, taking snapshots, and editing the virtual
machine settings. View administrators can, however, still monitor the local
session and access the vCenter Server version to remove access or roll back the
desktop.
Backups
During backups, a snapshot is taken on the client system, to preserve the state
of the checked-out virtual machine. The delta between this snapshot and the
snapshot in vCenter is replicated to vCenter and merged with the snapshot
there. The View desktop in vCenter Server is updated with all new data and
configurations, but the local desktop remains checked out on the local system
and the lock remains in place in vCenter Server.
Rollbacks
During rollbacks, the local View desktop is discarded and the lock is released
in vCenter Server. Future client connections are directed to the View desktop
in vCenter Server until the desktop is checked out again.
Check-ins
When a View desktop is checked in, a snapshot is taken on the client system,
to preserve the state of the virtual machine. The delta between this snapshot
and the snapshot in vCenter is replicated to vCenter and merged with the
snapshot there. The virtual machine in vCenter Server is unlocked. Future
client connections are directed to the View desktop in vCenter Server until the
desktop is checked out again.
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VMware View Architecture Planning
The data on each local system is encrypted with AES. 128-bit encryption is the default, but you can configure
192-bit or 256-bit encryption. The desktop has a lifetime controlled through policy. If the client loses contact
with View Connection Server, the maximum time without server contact is the period in which the user can
continue to use the desktop before the user is refused access. Similarly, if user access is removed, the client
system becomes inaccessible when the cache expires or after the client detects this change through View
Connection Server.
View Client with Local Mode has the following limitations and restrictions:
n
You must have a View license that includes the Local Mode component.
n
End users cannot access their local desktop while rollbacks and check-ins are taking place.
n
This feature is available only for virtual machines that are managed by vCenter Server.
n
Assigning application packages created with VMware ThinApp is not supported on local desktops.
n
For security reasons, you cannot access the host CD-ROM from within the View desktop.
n
Also for security reasons, you cannot copy and paste text or system objects such as files and folders between
the local system and the View desktop.
Accessing USB Devices Connected to a Local Computer
Administrators can configure the ability to use USB devices, such as thumb flash drives, VoIP (voice-over-IP)
devices, and printers, from a View desktop. This feature is called USB redirection.
When you use this feature, most USB devices that are attached to the local client system become available from
a menu in View Client. You use the menu to connect and disconnect the devices.
USB devices that do not appear in the menu, but are available in a View desktop, include smart card readers
and human interface devices such as keyboards and pointing devices. The View desktop and the local computer
use these devices at the same time.
This feature has the following limitations:
n
When you access a USB device from a menu in View Client and use the device in a View desktop, you
cannot access the device on the local computer.
n
USB redirection is not supported on Windows 2000 systems or for View desktops sourced from Microsoft
Terminal Servers.
Printing from a View Desktop
The virtual printing feature allows end users with View Client on Windows systems to use local or network
printers from a View desktop without requiring that additional print drivers be installed in the View desktop.
For each printer available through this feature, you can set preferences for data compression, print quality,
double-sided printing, color, and so on.
After a printer is added on the local Windows computer, View adds that printer to the list of available printers
on the View desktop. No further configuration is required. Users who have administrator privileges can still
install printer drivers on the View desktop without creating a conflict with the virtual printing component.
To send print jobs to a USB printer, you can either use the USB redirection feature or use the virtual printing
feature.
In addition, the location-based printing capabilities as of View 4.5 allow IT organizations to map View desktops
to the printer that is closest to the endpoint client device. For example, as a doctor moves from room to room
in a hospital, each time the doctor prints a document, the print job is sent to the nearest printer.
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Chapter 2 Planning a Rich User Experience
Streaming Multimedia to a View Desktop
Wyse MMR (multimedia redirection) enables full-fidelity playback when multimedia files are streamed to a
View desktop.
The MMR feature supports the media file formats that the client system supports, because local decoders must
exist on the client. File formats include MPEG2, WMV, AVI, and WAV, among others.
This feature has the following limitations:
n
For best quality, use Windows Media Player 10 or later, and install it on both the local computer, or client
access device, and the View desktop.
n
The Wyse MMR port, which is 9427 by default, must be added as a firewall exception in the View desktop.
n
MMR is not supported on Windows 7 clients or virtual desktops.
Although MMR is not supported on Windows 7 virtual desktops, if the Windows 7 desktop has 1GB of
RAM and 2 virtual CPUs, you can use PCoIP to play 480p- and 720p-formatted videos at native resolutions.
For 1080p, you might need to make the window smaller than full screen size.
Using Single Sign-On for Logging In to a View Desktop
The single-sign-on (SSO) feature allows you to configure View Manager so that end users are prompted to log
in only once.
If you do not use the single-sign-on feature, end users must log in twice. They are first prompted to log in to
View Connection Server and then are prompted log in to their View desktop. If smart cards are also used, end
users must sign in three times because users must also log in when the smart card reader prompts them for a
PIN.
This feature includes the Graphical Identification and Authentication (GINA) dynamic-link library for
Windows XP and a credential provider dynamic-link library for Windows Vista.
Using Multiple Monitors with a View Desktop
Regardless of the display protocol, you can use multiple monitors with a View desktop.
If you use PCoIP, the display protocol from VMware, you can adjust the display resolution and rotation
separately for each monitor. PCoIP allows a true multiple-monitor session rather than a span mode session.
A span mode remote session is actually a single-monitor session. The monitors must be the same size and
resolution, and the monitor layout must fit within a bounding box. If you maximize an application window,
the window spans across all monitors.
In a true multiple-monitor session, monitors can have different resolutions and sizes, and a monitor can be
pivoted. If you maximize an application window, the window expands to the full screen of only the monitor
that contains it.
This feature has the following limitations:
n
The maximum number of monitors that you can use to display a View desktop is 10 if you use the RDP
display protocol and 4 if you use PCoIP.
n
If you use Microsoft RDP display protocol, you must have Microsoft Remote Desktop Connection (RDC)
6.0 or higher installed in the View desktop.
n
If you use a View desktop in local mode, no remote display protocol is used. You can use multiple monitors
in span mode.
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VMware View Architecture Planning
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Managing Desktop Pools from a
Central Location
3
You can create pools that include one or hundreds of virtual desktops. As a desktop source, you can use virtual
machines, physical machines, and Windows Terminal Services servers. Create one virtual machine as a base
image, and VMware View can generate a pool of virtual desktops from that image. You can easily install or
stream applications to pools with VMware ThinApp.
This chapter includes the following topics:
n
“Advantages of Desktop Pools,” on page 23
n
“Reducing and Managing Storage Requirements,” on page 24
n
“Application Provisioning,” on page 25
n
“Using Active Directory GPOs to Manage Users and Desktops,” on page 27
Advantages of Desktop Pools
VMware View offers the ability to create and provision pools of desktops as its basis of centralized
management.
You create a virtual desktop pool from one of the following sources:
n
A physical system such as a physical desktop PC or a Windows Terminal Services server
n
A virtual machine that is hosted on an ESX server and managed by vCenter Server
n
A virtual machine that runs on VMware Server or some other virtualization platform that supports View
Agent
If you use a vSphere virtual machine as a desktop source, you can automate the process of making as many
identical virtual desktops as you need. You can set a minimum and maximum number of virtual desktops to
be generated for the pool. Setting these parameters ensures that you always have enough View desktops
available for immediate use but not so many that you overuse available resources.
Using pools to manage desktops allows you to apply settings or deploy applications to all virtual desktops in
a pool. The following examples show some of the settings available:
n
Specify which remote display protocol to use as the default for the View desktop and whether to let end
users override the default.
n
Configure the display quality and bandwidth throttling of Adobe Flash animations.
n
If using a virtual machine, specify whether to power off the virtual machine when it is not in use and
whether to delete it altogether.
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VMware View Architecture Planning
n
If using vSphere 4.1, specify whether to use a Microsoft Sysprep customization specification or QuickPrep
from VMware. Sysprep generates a unique SID and GUID for each virtual machine in the pool.
n
Specify whether the View desktop can or must be downloaded and run on a local client system.
In addition, using desktop pools provides many conveniences.
Dedicated-assignment
pools
Each user is assigned a particular View desktop and returns to the same virtual
desktop at each login. Users can personalize their desktops, install applications,
and store data.
Floating-assignment
pools
The virtual desktop is optionally deleted and re-created after each use, offering
a highly controlled environment. A floating-assignment desktop is like a
computer lab or kiosk environment where each desktop is loaded with the
necessary applications and all desktops have access to necessary data.
Using floating-assignment pools also allows you to create a pool of desktops
that can be used by shifts of users. For example, a pool of 100 desktops could
be used by 300 users if they worked in shifts of 100 users at a time.
Reducing and Managing Storage Requirements
Using virtual desktops that are managed by vCenter Server provides all the storage efficiencies that were
previously available only for virtualized servers. Using View Composer increases the storage savings because
all desktops in a pool share a virtual disk with a base image.
n
Managing Storage with vSphere on page 24
VMware vSphere lets you virtualize disk volumes and file systems so that you can manage and configure
storage without having to consider where the data is physically stored.
n
Reducing Storage Requirements with View Composer on page 25
Because View Composer creates desktop images that share virtual disks with a base image, you can
reduce the required storage capacity by 50 to 90 percent.
Managing Storage with vSphere
VMware vSphere lets you virtualize disk volumes and file systems so that you can manage and configure
storage without having to consider where the data is physically stored.
Fibre Channel SAN arrays, iSCSI SAN arrays, and NAS arrays are widely used storage technologies supported
by VMware vSphere to meet different datacenter storage needs. The storage arrays are connected to and shared
between groups of servers through storage area networks. This arrangement allows aggregation of the storage
resources and provides more flexibility in provisioning them to virtual machines.
With View 4.5 and later and vSphere 4.1 and later, you can now also use the following features:
24
n
vStorage thin provisioning, which lets you start out with as little disk space as necessary and grow the
disk to add space later
n
Tiered storage, which allows you to distribute virtual disks in the View environment across highperformance storage and lower-cost storage tiers, to maximize performance and cost savings
n
Local storage on the ESX server for the virtual machine swap files in the guest operating system
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Chapter 3 Managing Desktop Pools from a Central Location
Reducing Storage Requirements with View Composer
Because View Composer creates desktop images that share virtual disks with a base image, you can reduce
the required storage capacity by 50 to 90 percent.
View Composer uses a base image, or parent virtual machine, and creates a pool of up to 512 linked-clone
virtual machines. Each linked clone acts like an independent desktop, with a unique host name and IP address,
yet the linked clone requires significantly less storage.
When you create a linked-clone desktop pool, a full clone is first made from the parent virtual machine. The
full clone, or replica, and the clones linked to it can be placed on the same data store, or LUN (logical unit
number). If necessary, you can use the rebalance feature to move the replica and linked clones from one LUN
to another.
Alternatively, you can place View Composer replicas and linked clones on separate datastores with different
performance characteristics. For example, you can store the replica virtual machines on a solid-state drive
(SSD). Solid-state drives have low storage capacity and high read performance, typically supporting tens of
thousands of I/Os per second (IOPS). You can store linked clones on traditional, spinning media-backed
datastores. These disks provide lower performance, but are less expensive and provide higher storage capacity,
which makes them suited for storing the many linked clones in a large pool. Tiered storage configurations can
be used to cost-effectively handle intensive I/O scenarios such as simultaneous rebooting of many virtual
machines or running scheduled antivirus scans.
When you create a linked-clone pool, you can also optionally configure a separate, disposable virtual disk to
store the guest operating system's paging and temp files that are generated during user sessions. When the
virtual machine is powered off, View Manager deletes the disposable disk. Using disposable disks can save
storage space by slowing the growth of linked clones and reducing the space used by powered off virtual
machines.
When you create dedicated-assignment desktop pools, View Composer can also optionally create a separate
persistent virtual disk for each virtual desktop. The end user's Windows profile and application data are saved
on the persistent disk. When a linked clone is refreshed, recomposed, or rebalanced, the contents of the
persistent virtual disk are preserved. VMware recommends that you keep View Composer persistent disks on
a separate datastore. You can then back up the whole LUN that holds persistent disks.
For more information, see the best-practices guide called Storage Considerations for VMware View.
Application Provisioning
With VMware View, you have several options regarding application provisioning: You can use traditional
application provisioning techniques, you can distribute application packages created with VMware ThinApp,
or you can deploy applications as part of a View Composer base image.
n
Deploying Applications and System Updates with View Composer on page 26
Because linked-clone desktop pools share a base image, you can quickly deploy updates and patches by
updating the parent virtual machine.
n
Managing VMware ThinApp Applications in View Administrator on page 26
VMware ThinApp™ lets you package an application into a single file that runs in a virtualized application
sandbox. This strategy results in flexible, conflict-free application provisioning.
n
Using Existing Processes for Application Provisioning on page 27
With VMware View, you can continue to use the application provisioning techniques that your company
currently uses. Two additional considerations include managing server CPU usage and storage I/O and
determining whether users are permitted to install applications.
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VMware View Architecture Planning
Deploying Applications and System Updates with View Composer
Because linked-clone desktop pools share a base image, you can quickly deploy updates and patches by
updating the parent virtual machine.
The recompose feature allows you to make changes to the parent virtual machine, take a snapshot of the new
state, and push the new version of the image to all, or a subset of, users and desktops. You can use this feature
for the following tasks:
n
Applying operating system and software patches and upgrades
n
Applying service packs
n
Adding applications
n
Adding virtual devices
n
Changing other virtual machine settings, such as available memory
You can create a View Composer persistent disk that contains user settings and other user-generated data. This
persistent disk is not affected by a recompose operation. When a linked clone is deleted, you can preserve the
user data. When an employee leaves the company, another employee can access the departing employee's user
data. A user who has multiple desktops can consolidate the user data on a single desktop.
If you want to disallow users from adding or removing software or changing settings, you can use the refresh
feature to bring the desktop back to its default values. This feature also reduces the size of linked clones, which
tend to grow over time.
Managing VMware ThinApp Applications in View Administrator
VMware ThinApp™ lets you package an application into a single file that runs in a virtualized application
sandbox. This strategy results in flexible, conflict-free application provisioning.
ThinApp provides application virtualization by decoupling an application from the underlying operating
system and its libraries and framework and bundling the application into a single executable file called an
application package. As of View 4.5, you can use View Administrator to distribute ThinApp applications to
desktops and pools.
After you create a virtualized application with ThinApp, you can choose to either stream the application from
a shared file server or install the application on the virtual desktops. If you configure the virtualized application
for streaming, you must address the following architectural considerations:
n
Access for specific user groups to specific application repositories, where the application package is stored
n
Storage configuration for the application repository
n
Network traffic generated by streaming, which depends largely on the type of application
For streamed applications, users launch the applications by using a desktop shortcut.
If you assign a ThinApp package so that it is installed on a virtual desktop, the architectural considerations
are similar to those that you address when you use traditional MSI-based software provisioning. Storage
configuration for the application repository is a consideration both for streamed applications and for ThinApp
packages installed in virtual desktops.
NOTE Assigning application packages created with VMware ThinApp is not supported for View desktops
that are downloaded and used in local mode.
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Chapter 3 Managing Desktop Pools from a Central Location
Using Existing Processes for Application Provisioning
With VMware View, you can continue to use the application provisioning techniques that your company
currently uses. Two additional considerations include managing server CPU usage and storage I/O and
determining whether users are permitted to install applications.
If you push applications out to large numbers of virtual desktops at exactly the same time, you might see
significant spikes in CPU usage and storage I/O. These peak workloads can have noticeable effects on desktop
performance. As a best practice, schedule application updates to occur during off-peak hours and stagger
updates to desktops if possible. You must also verify that your storage solution is designed to support such
workloads.
If your company allows users to install applications, you can continue your current policies, but you cannot
take advantage of View Composer features such as refreshing and recomposing the desktop. With View
Composer, if an application is not virtualized or otherwise included in the user's profile or data settings, that
application is discarded whenever a View Composer refresh, recompose, or rebalance operation occurs. In
many cases, this ability to tightly control which applications are installed is a benefit. View Composer desktops
are easy to support because they are kept close to a known good configuration.
If users have firm requirements for installing their own applications and having those applications persist for
the lifetime of the virtual desktop, instead of using View Composer for application provisioning, you can create
full persistent desktops and allow users to install applications.
Using Active Directory GPOs to Manage Users and Desktops
VMware View includes many Group Policy administrative (ADM) templates for centralizing the management
and configuration of View components and View desktops.
After you import these templates into Active Directory, you can use them to set policies that apply to the
following groups and components:
n
All systems regardless of which user logs in
n
All users regardless of the system they log in to
n
View Connection Server configuration
n
View Client configuration
n
View Agent configuration
After a GPO is applied, properties are stored in the local Windows registry of the specified component.
You can use GPOs to set all the policies that are available from the View Administrator user interface (UI). You
can also use GPOs to set policies that are not available from the UI. For a complete list and description of the
settings available through ADM templates, see the VMware View Administration document.
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VMware View Architecture Planning
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Architecture Design Elements and
Planning Guidelines
4
A typical VMware View architecture design uses a building block strategy to achieve scalability. Each building
block definition can vary, based on hardware configuration, View and vSphere software versions used, and
other environment-specific design factors.
This chapter describes a validated example building block that consists of components that support up to 2,000
virtual desktops using vSphere 4.1. The overall deployment integrates 5 of these building blocks for a total of
10,000 virtual desktops in what is termed a "pod."
This architecture provides a standard, scalable design that you can adapt to your enterprise environment and
special requirements. This chapter includes key details about requirements for memory, CPU, storage capacity,
network components, and hardware to give IT architects and planners a practical understanding of what is
involved in deploying a VMware View solution.
This chapter includes the following topics:
n
“Virtual Machine Requirements,” on page 29
n
“VMware View ESX Node,” on page 34
n
“Desktop Pools for Specific Types of Workers,” on page 35
n
“Desktop Virtual Machine Configuration,” on page 38
n
“vCenter and View Composer Virtual Machine Configuration and Desktop Pool Maximums,” on
page 40
n
“View Connection Server Maximums and Virtual Machine Configuration,” on page 40
n
“View Transfer Server Virtual Machine Configuration and Storage,” on page 41
n
“vSphere Clusters,” on page 42
n
“VMware View Building Blocks,” on page 43
n
“VMware View Pod,” on page 46
Virtual Machine Requirements
When you plan the specifications for View desktops, the choices that you make regarding RAM, CPU, and
disk space have a significant effect on your choices for server and storage hardware and expenditures.
n
Planning Based on Types of Workers on page 30
For many configuration elements, including RAM, CPU, and storage sizing, requirements depend largely
on the type of worker who uses the virtual desktop and on the applications that must be installed.
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VMware View Architecture Planning
n
Estimating Memory Requirements for Virtual Desktops on page 31
RAM costs more for servers than it does for PCs. Because the cost of RAM is a high percentage of overall
server hardware costs and total storage capacity needed, determining the correct memory allocation is
crucial to planning your desktop deployment.
n
Estimating CPU Requirements for Virtual Desktops on page 33
When estimating CPU, you must gather information about the average CPU utilization for various types
of workers in your enterprise. In addition, calculate that another 10 to 25 percent of processing power is
required for virtualization overhead and peak periods of usage.
n
Choosing the Appropriate System Disk Size on page 33
When allocating disk space, provide only enough space for the operating system, applications, and
additional content that users might install or generate. Usually this amount is smaller than the size of
the disk that is included on a physical PC.
Planning Based on Types of Workers
For many configuration elements, including RAM, CPU, and storage sizing, requirements depend largely on
the type of worker who uses the virtual desktop and on the applications that must be installed.
For architecture planning, workers can be categorized into several types.
30
Task workers
Task workers and administrative workers perform repetitive tasks within a
small set of applications, usually at a stationary computer. The applications are
usually not as CPU- and memory-intensive as the applications used by
knowledge workers. Task workers who work specific shifts might all log in to
their virtual desktops at the same time. Task workers include call center
analysts, retail employees, warehouse workers, and so on.
Knowledge workers
Knowledge workers' daily tasks include accessing the Internet, using email,
and creating complex documents, presentations, and spreadsheets. Knowledge
workers include accountants, sales managers, marketing research analysts, and
so on.
Power users
Power users include application developers and people who use graphicsintensive applications.
Employees who use
desktops in local mode
only
These users download and run their View desktops only on their local systems,
which reduces datacenter costs associated with bandwidth, memory, and CPU
resources. Scheduled replications ensure that systems and data are backed up.
Administrators configure how often end users' systems must contact
View Manager to avoid being locked out.
Kiosk users
These users need to share a desktop that is placed in a public place. Examples
of kiosk users include students using a shared computer in a classroom, nurses
at nursing stations, and computers used for job placement and recruiting. These
desktops require automatic login. Authentication can be done through certain
applications if necessary.
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Chapter 4 Architecture Design Elements and Planning Guidelines
Estimating Memory Requirements for Virtual Desktops
RAM costs more for servers than it does for PCs. Because the cost of RAM is a high percentage of overall server
hardware costs and total storage capacity needed, determining the correct memory allocation is crucial to
planning your desktop deployment.
If the RAM allocation is too low, storage I/O can be negatively affected because too much memory swapping
occurs. If the RAM allocation is too high, storage capacity can be negatively affected because the paging file
in the guest operating system and the swap and suspend files for each virtual machine grow too large.
NOTE This topic addresses issues regarding memory allocation for remote access to View desktops. If users
run View desktops in local mode, on their client systems, the amount of memory used is some proportion of
that available on the client device.
You need enough memory to run the host operating system on the client computer, plus the memory required
for the View desktop's operating system and for applications on the client computer and the View desktop.
VMware recommends that you have 2GB or more for Windows XP and Windows Vista, and 3GB or more for
Windows 7.
If you attempt to check out a desktop that is configured in vCenter Server to require more memory than the
local client system can accommodate, you will not be able to check out the desktop unless you change a
Windows registry setting. For instructions, see the VMware View Administration document.
RAM Sizing Impact on Performance
When allocating RAM, avoid choosing an overly conservative setting. Take the following considerations into
account:
n
Insufficient RAM allocations can cause excessive guest swapping, which can generate I/O that causes
significant performance degradations and increases storage I/O load.
n
VMware ESX supports sophisticated memory resource management algorithms such as transparent
memory sharing and memory ballooning, which can significantly reduce the physical RAM needed to
support a given guest RAM allocation. For example, even though 2GB might be allocated to a virtual
desktop, only a fraction of that number is consumed in physical RAM.
n
Because virtual desktop performance is sensitive to response times, on the ESX server, set nonzero values
for RAM reservation settings. Reserving some RAM guarantees that idle but in-use desktops are never
completely swapped out to disk. It can also reduce storage space consumed by ESX swap files. However,
higher reservation settings affect your ability to overcommit memory on an ESX server and might affect
VMotion maintenance operations.
RAM Sizing Impact on Storage
The amount of RAM that you allocate to a virtual machine is directly related to the size of the certain files that
the virtual machine uses. To access the files in the following list, use the Windows guest operating system to
locate the Windows page and hibernate files, and use the ESX server's file system to locate the ESX swap and
suspend files.
Windows page file
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By default, this file is sized at 150 percent of guest RAM. This file, which is by
default located at C:\pagefile.sys, causes thin-provisioned storage to grow
because it is accessed frequently. On linked-clone virtual machines, the page
file and temporary files can be redirected to a separate virtual disk that is
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VMware View Architecture Planning
deleted when the virtual machines are powered off. Disposable page-file
redirection saves storage, slowing the growth of linked clones and also can
improve performance. Although you can adjust the size from within Windows,
doing so might have a negative effect on application performance.
Windows hibernate file
for laptops
This file can equal 100 percent of guest RAM. You can safely delete this file
because it is not needed in View deployments, even if you use View Client with
Local Mode.
ESX swap file
This file, which has a .vswp extension, is created if you reserve less than 100
percent of a virtual machine's RAM. The size of the swap file is equal to the
unreserved portion of guest RAM. For example, if 50 percent of guest RAM is
reserved and guest RAM is 2GB, the ESX swap file is 1GB. This file can be stored
on the local datastore on the ESX host or cluster.
ESX suspend file
This file, which has a .vmss extension, is created if you set the desktop pool
logoff policy so that the virtual desktop is suspended when the end user logs
off. The size of this file is equal to the size of guest RAM.
RAM Sizing for Specific Monitor Configurations When Using PCoIP
If you use PCoIP, the display protocol from VMware, the amount of extra RAM that the ESX host requires
depends in part on the number of monitors configured for end users and on the display resolution. Table 4-1
lists the amount of overhead RAM required for various configurations. The amounts of memory listed in the
columns are in addition to the amount of memory required for other PCoIP functionality.
Table 4-1. PCoIP Client Display Overhead
Display
Resolution
Standard
Width, in Pixels
Height, in Pixels
1-Monitor
Overhead
2-Monitor
Overhead
4-Monitor
Overhead
VGA
640
480
2.34MB
4.69MB
9.38MB
SVGA
800
600
3.66MB
7.32MB
14.65MB
720p
1280
720
7.03MB
14.65MB
28.13MB
UXGA
1600
1200
14.65MB
29.30MB
58.59MB
1080p
1920
1080
15.82MB
31.64MB
63.28MB
WUXGA
1920
1200
17.58MB
35.16MB
70.31MB
QXGA
2048
1536
24.00MB
48.00MB
96.00MB
WQXGA
2560
1600
31.25MB
62.50MB
125.00MB
When you consider these requirements, note that virtual machine configuration of allocated RAM does not
change. That is, you do not need to allocate 1GB of RAM for applications and another 31MB for dual 1080p
monitors. Instead, consider the overhead RAM when calculating the total physical RAM required for each ESX
server. Add the guest operating system RAM to the overhead RAM and multiply by the number of virtual
machines.
RAM Sizing for Specific Workloads and Operating Systems
Because the amount of RAM required can vary widely, depending on the type of worker, many companies
conduct a pilot phase to determine the correct setting for various pools of workers in their enterprise.
A good starting point is to allocate 1GB for Windows XP desktops and 32-bit Windows Vista and Windows 7
desktops and 2GB for 64-bit Windows 7 desktops. During a pilot, monitor the performance and disk space
used with various types of workers and make adjustments until you find the optimal setting for each pool of
workers.
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Estimating CPU Requirements for Virtual Desktops
When estimating CPU, you must gather information about the average CPU utilization for various types of
workers in your enterprise. In addition, calculate that another 10 to 25 percent of processing power is required
for virtualization overhead and peak periods of usage.
NOTE This topic addresses issues regarding CPU requirements when accessing View desktops remotely. If
users run a View desktop in local mode on their client systems, the View desktop uses the available CPUs on
the client device, up to 2 CPUs.
CPU requirements vary by worker type. During your pilot phase, use a performance monitoring tool, such as
Perfmon in the virtual machine, esxtop in ESX, or vCenter performance monitoring tools, to understand both
the average and peak CPU use levels for these groups of workers. Also use the following guidelines:
n
Software developers or other power uses with high-performance needs might have much higher CPU
requirements than knowledge workers and task workers. Dual virtual CPUs are recommended for
compute-intensive tasks or for Windows 7 desktops that need to play 720p video using the PCoIP display
protocol.
n
Single virtual CPUs are generally recommended for other cases.
Because many virtual machines run on one server, CPU can spike if agents such as antivirus agents all check
for updates at exactly the same time. Determine which agents and how many agents could cause performance
issues and adopt a strategy for addressing these issues. For example, the following strategies might be helpful
in your enterprise:
n
Use View Composer to update images rather than having software management agents download
software updates to each individual virtual desktop.
n
Schedule antivirus and software updates to run at nonpeak hours, when few users are likely to be logged
in.
n
Stagger or randomize when updates occur.
As an informal initial sizing approach, to start, assume that each virtual machine requires 1/8 to 1/10 of a CPU
core as the minimum guaranteed compute power. That is, plan a pilot that uses 8 to 10 virtual machines per
core. For example, if you assume 8 virtual machines per core and have a 2-socket 8-core ESX server, you can
host 128 virtual machines on the server during the pilot. Monitor the overall CPU usage on the host during
this period and ensure that it rarely exceeds a safety margin such as 80 percent to give enough headroom for
spikes.
Choosing the Appropriate System Disk Size
When allocating disk space, provide only enough space for the operating system, applications, and additional
content that users might install or generate. Usually this amount is smaller than the size of the disk that is
included on a physical PC.
Because datacenter disk space usually costs more per gigabyte than desktop or laptop disk space in a traditional
PC deployment, optimize the operating system image size. The following suggestions might help optimize
image size:
n
Remove unnecessary files. For example, reduce the quotas on temporary Internet files.
n
Choose a virtual disk size that is sufficient to allow for future growth, but is not unrealistically large.
n
Use centralized file shares or a View Composer persistent disk for user-generated content and userinstalled applications.
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The amount of storage space required must take into account the following files for each virtual desktop:
n
The ESX suspend file is equivalent to the amount of RAM allocated to the virtual machine.
n
The Windows page file is equivalent to 150 percent of RAM.
n
Log files take up approximately 100MB for each virtual machine.
n
The virtual disk, or .vmdk file, must accommodate the operating system, applications, and future
applications and software updates. The virtual disk must also accommodate local user data and userinstalled applications if they are located on the virtual desktop rather than on file shares.
If you use View Composer, the .vmdk files grow over time, but you can control the amount of growth by
scheduling View Composer refresh operations, setting a storage over-commit policy for View desktop
pools, and redirecting Windows page and temporary files to a separate, nonpersistent disk.
You can also add 15 percent to this estimate to be sure that users do not run out of disk space.
VMware View ESX Node
A node is a single VMware ESX server that hosts virtual machine desktops in a VMware View deployment.
VMware View is most cost-effective when you maximize the consolidation ratio, which is the number of
desktops hosted on an ESX server. Although many factors affect server selection, if you are optimizing strictly
for acquisition price, you must find server configurations that have an appropriate balance of processing power
and memory.
There is no substitute for measuring performance under actual, real world scenarios, such as in a pilot, to
determine an appropriate consolidation ratio for your environment and hardware configuration.
Consolidation ratios can vary significantly, based on usage patterns and environmental factors. Use the
following guidelines:
n
As a general framework, consider compute capacity in terms of 8 to 10 virtual desktops per CPU core. For
information about calculating CPU requirements for each virtual machine, see “Estimating CPU
Requirements for Virtual Desktops,” on page 33.
n
Think of memory capacity in terms of virtual desktop RAM, host RAM, and overcommit ratio. Although
you can have between 8 and 10 virtual desktops per CPU core, if virtual desktops have 1GB or more of
RAM, you must also carefully consider physical RAM requirements. For information about calculating
the amount of RAM required per virtual machine, see “Estimating Memory Requirements for Virtual
Desktops,” on page 31.
Note that physical RAM costs are not linear and that in some situations, it can be cost-effective to purchase
more smaller servers that do not use expensive DIMM chips. In other cases, rack density, storage
connectivity, manageability and other considerations can make minimizing the number of servers in a
deployment a better choice.
n
Finally, consider cluster requirements and any failover requirements. For more information, see
“Determining Requirements for High Availability,” on page 42.
For information about specifications of ESX hosts in vSphere, see the VMware vSphere Configuration
Maximums document.
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Desktop Pools for Specific Types of Workers
VMware View provides many features to help you conserve storage and reduce the amount of processing
power required for various use cases. Many of these features are available as pool settings.
The most fundamental question to consider is whether a certain type of user needs a stateful desktop image
or a stateless desktop image. Users who need a stateful desktop image have data in the operating system image
itself that must be preserved, maintained, and backed up. For example, these users install some of their own
applications or have data that cannot be saved outside of the virtual machine itself, such as on a file server or
in an application database.
Stateless desktop
images
Stateless architectures have many advantages, such as being easier to support,
allowing View Composer based image management, and having lower storage
costs. Other benefits include a limited need to back up the linked-clone virtual
machines and easier, less expensive disaster recovery and business continuity
options.
Stateful desktop images
These images require traditional image management techniques. Stateful
images can have low storage costs in conjunction with certain storage system
technologies. Backup and recovery technologies such as VMware Consolidated
Backup and VMware Site Recovery Manager are important when considering
strategies for backup, disaster recovery, and business continuity.
You create stateless desktop images by using View Composer and creating floating-assignment pools of linkedclone virtual machines. You create stateful desktop images by creating dedicated-assignment pools of full
virtual machines. Some storage vendors have cost-effective storage solutions for stateful desktop images. These
vendors often have their own best practices and provisioning utilities. Using one of these vendors might require
that you create a manual dedicated-assignment pool.
n
Pools for Task Workers on page 36
You can standardize on stateless desktop images for task workers so that the image is always in a wellknown, easily supportable configuration and so that workers can log in to any available desktop.
n
Pools for Knowledge Workers and Power Users on page 36
Knowledge workers need to be able to create complex documents and have them persist on the desktop.
Power users need to be able to install their own applications and have them persist. Depending on the
nature and amount of personal data that must be retained, the desktop can be stateful or stateless.
n
Pools for Mobile Users on page 37
These users can check out a View desktop and run it locally on their laptop or desktop even without a
network connection.
n
Pools for Kiosk Users on page 38
Kiosk users might include customers at airline check-in stations, students in classrooms or libraries,
medical personnel at medical data entry workstations, or customers at self-service points. Accounts
associated with client devices rather than users are entitled to use these desktop pools because users do
not need to log in to use the client device or the View desktop. Users can still be required to provide
authentication credentials for some applications.
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Pools for Task Workers
You can standardize on stateless desktop images for task workers so that the image is always in a well-known,
easily supportable configuration and so that workers can log in to any available desktop.
Because task workers perform repetitive tasks within a small set of applications, you can create stateless
desktop images, which help conserve storage space and processing requirements. Use the following pool
settings:
n
Create an automated pool so that desktops can be created when the pool is created or can be generated
on demand based on pool usage.
n
Use floating assignment so that users log in to any available desktop. This setting reduces the number of
desktops required if everyone does not need to be logged in at the same time.
n
Create View Composer linked-clone desktops so that desktops share the same base image and use less
storage space in the datacenter than full virtual machines.
n
Determine what action, if any, to take when users log off. Disks grow over time. You can conserve disk
space by refreshing the desktop to its original state when users log off. You can also set a schedule for
periodically refreshing desktops. For example, you can schedule desktops to refresh daily, weekly, or
monthly.
Pools for Knowledge Workers and Power Users
Knowledge workers need to be able to create complex documents and have them persist on the desktop. Power
users need to be able to install their own applications and have them persist. Depending on the nature and
amount of personal data that must be retained, the desktop can be stateful or stateless.
Because power users and knowledge workers, such as accountants, sales managers, marketing research
analysts, need to be able to create and retain documents and settings, you create dedicated-assignment
desktops for them. For knowledge workers do not need user-installed applications except for temporary use,
you can create stateless desktop images and save all their personal data outside of the virtual machine, on a
file server or in an application database. For other knowledge workers and for power users, you can create
stateful desktop images. Use the following pool settings:
36
n
Use dedicated assignment so that each knowledge worker or power user logs in to the same desktop every
time.
n
Use vStorage thin provisioning so that at first, each desktop uses only as much storage space as the disk
needs for its initial operation.
n
If knowledge workers do not need user-installed applications except for temporary use, you can create
View Composer linked-clone desktops. These stateless desktop images share the same base image and
use less storage space than full virtual machines.
n
If you use View Composer linked-clone desktops, either implement a roaming or virtual profile based
solution to store user data centrally or configure a persistent disk for the desktop. Keep in mind, however,
that after you refresh or recompose a desktop, the centrally stored data and persistent disk are retained,
but the disk that contains the operating system and applications is not retained.
n
For power users and knowledge workers who need to install their own applications, which adds data to
the operating system disk, create full virtual machine desktops. These users need stateful desktop images.
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Chapter 4 Architecture Design Elements and Planning Guidelines
Pools for Mobile Users
These users can check out a View desktop and run it locally on their laptop or desktop even without a network
connection.
View Client with Local Mode provides benefits for both end users and IT administrators. For administrators,
local mode allows View security policies to extend to laptops that have previously been unmanaged.
Administrators can retain tight control over the applications that run on the View desktop and can centrally
manage the desktop just as they do remote View desktops. With local mode, all the benefits of VMware View
can also extend to remote or branch offices that have slow or unreliable networks.
For end users, benefits include the flexibility of continuing to use their own computers online or offline. The
View desktop is automatically encrypted and can easily be synchronized with an image in the datacenter for
purposes of disaster recovery.
General Recommendations
Local mode users might need to access their desktop applications and data from their laptop when no network
connection is available. In addition, they might need this data to be regularly and automatically backed up to
the datacenter in the event that the laptop is ever lost, damaged, or stolen. To provide these capabilities, you
can use the following pool settings.
n
When creating a virtual machine to base the pool on, configure the minimum amount of RAM and virtual
CPUs required by the guest operating system. Desktops that run in local mode adjust the amount of
memory and processing power they use based on that available from the client computer.
n
Create an automated pool so that desktops can be created when the pool is created or can be generated
on demand based on pool usage.
n
Use dedicated assignment because local mode users need to log in to the same desktop every time.
n
Create View Composer linked-clone desktops so that desktops share the same base image and use less
storage space in the datacenter than full virtual machines.
n
If you want the provisioning process to generate a unique local computer SID and GUID for each linked
clone in the pool, select a Sysprep customization specification when you create the pool. Sysprep creates
new SIDs and GUIDs during the initial provisioning and after recompose operations. Because you are not
likely to recompose local mode pools, the SIDs and GUIDs are not likely to change.
n
Include in the pool only desktops that are intended to be used in local mode. Local mode virtual machines
can be placed on datastores with lower IOPS requirements than storage intended to support large numbers
of remote View desktops.
Additional Recommendations Targeting Minimal Capital Expenditure
You can reduce the number of ESX servers required for your local mode pool if you increase the number of
virtual machines per ESX server. An ESX 4.1 server can host up to 500 virtual machines if most are not powered
on at the same time, as is frequently the case for local mode pools.
Use the following recommendations to reduce the amount of bandwidth and I/O operations required by each
virtual machine and maximize the number of virtual machines on an ESX server.
n
Set a View policy so that end users must use their View desktops in local mode only. With this setting,
the virtual machines in the datacenter remain locked and powered off.
n
Set local mode policies so that end users cannot initiate desktop rollbacks, data backups, or check-ins to
the datacenter.
n
Do not schedule automatic backups.
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n
Do not turn on SSL for provisioning or downloading local mode desktops.
n
If the performance of View Connection Server is affected by the number of local desktops, set the heartbeat
interval to be less frequent. The heartbeat lets View Connection Server know that the local desktop has a
network connection. The default interval is five minutes.
Pools for Kiosk Users
Kiosk users might include customers at airline check-in stations, students in classrooms or libraries, medical
personnel at medical data entry workstations, or customers at self-service points. Accounts associated with
client devices rather than users are entitled to use these desktop pools because users do not need to log in to
use the client device or the View desktop. Users can still be required to provide authentication credentials for
some applications.
View desktops that are set to run in kiosk mode use stateless desktop images because user data does not need
to be preserved in the operating system disk. Kiosk mode desktops are used with thin client devices or lockeddown PCs. You must ensure that the desktop application implements authentication mechanisms for secure
transactions, that the physical network is secure against tampering and snooping, and that all devices
connected to the network are trusted.
As a best practice, use dedicated View Connection Server instances to handle clients in kiosk mode, and create
dedicated organizational units and groups in Active Directory for the accounts of these clients. This practice
not only partitions these systems against unwarranted intrusion, but also makes it easier to configure and
administer the clients.
To set up kiosk mode, you must use the vdmadmin command-line interface and perform several procedures
documented in the topics about kiosk mode in the VMware View Administration document. As part of this setup,
you can use the following pool settings.
n
Create an automated pool so that desktops can be created when the pool is created or can be generated
on demand based on pool usage.
n
Use floating assignment so that users can access any available desktop in the pool.
n
Create View Composer linked-clone desktops so that desktops share the same base image and use less
storage space in the datacenter than full virtual machines.
n
Institute a refresh policy so that the desktop is refreshed frequently, such as at every user logoff.
n
Use an Active Directory GPO (group policy object) to configure location-based printing, so that the desktop
uses the nearest printer. For a complete list and description of the settings available through Group Policy
administrative (ADM) templates, see the VMware View Administration document.
n
Use a GPO if you want to override the default policy that enables connecting local USB devices to the
desktop when the desktop is launched or when USB devices are plugged in to the client computer.
Desktop Virtual Machine Configuration
Because the amount of RAM, CPU, and disk space that virtual desktops require depend on the guest operating
system, separate configuration examples are provided for Windows XP, Windows Vista, and Windows 7
virtual desktops.
The example settings for virtual machines such as memory, number of virtual processors, and disk space are
VMware View-specific.
The guidelines listed in Table 4-2 are for a standard Windows XP virtual desktop running in remote mode.
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Table 4-2. Desktop Virtual Machine Example for Windows XP
Item
Example
Operating system
32-bit Windows XP (with the latest service pack)
RAM
1GB (512MB low end, 2GB high end)
Virtual CPU
1
System disk capacity
16GB (8GB low end, 40GB high end)
User data capacity (as a persistent disk)
5GB (starting point)
Virtual SCSI adapter type
LSI Logic Parallel (not the default)
Virtual network adapter
Flexible (the default)
The amount of system disk space required depends on the number of applications required in the base image.
VMware has validated a setup that included 8GB of disk space. Applications included Microsoft Word, Excel,
PowerPoint, Adobe Reader, Internet Explorer, McAfee Antivirus, and PKZIP.
The amount of disk space required for user data depends on the role of the end user and organizational policies
for data storage. If you use View Composer, this data is kept on a persistent disk.
The guidelines listed in Table 4-3 are for a standard Windows Vista virtual desktop running in remote mode.
Table 4-3. Desktop Virtual Machine Example for Windows Vista
Item
Example
Operating system
32-bit Windows Vista (with the latest service pack)
RAM
1GB
Virtual CPU
1
System disk capacity
20GB (standard)
User data capacity (as a persistent disk)
5GB (starting point)
Virtual SCSI adapter type
LSI Logic Parallel (the default)
Virtual network adapter
E1000 (the default)
The guidelines listed in Table 4-4 are for a standard Windows 7 virtual desktop running in remote mode.
Table 4-4. Desktop Virtual Machine Example for Windows 7, Hosted on an ESX 4.1 Server
Item
Example
Operating system
32-bit Windows 7
RAM
1GB
Virtual CPU
1
System disk capacity
20GB (slightly less than standard)
User data capacity (as a persistent disk)
5GB (starting point)
Virtual SCSI adapter type
LSI Logic SAS (the default)
Virtual network adapter
E1000 (the default)
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vCenter and View Composer Virtual Machine Configuration and
Desktop Pool Maximums
You install both vCenter Server and View Composer on the same virtual machine. Because this virtual machine
is a server, it requires much more memory and processing power than a desktop virtual machine.
View Composer can create and provision up to 512 desktops per pool. View Composer can also perform a
recompose operation on up to 512 desktops at a time.
Although you can install vCenter Server and View Composer on a physical machine, this example uses a virtual
machine with the specifications listed in Table 4-5. The ESX/ESXi host for this virtual machine can be part of
a VMware HA cluster to guard against physical server failures.
This example assumes that you are using VMware View with vSphere 4.1 and vCenter Server 4.1.
Table 4-5. vCenter Server Virtual Machine Example and Pool Size Maximum
Item
Example
Operating system
64-bit Windows Server 2008 R2 Enterprise
RAM
4 GB
Virtual CPU
2
System disk capacity
40GB
Virtual SCSI adapter type
LSI Logic SAS (the default for Windows Server 2008)
Virtual network adapter
E1000 (the default)
Maximum View Composer pool size
512 desktops
IMPORTANT Place the database to which vCenter and View Composer connect on a separate virtual machine.
For guidance about database sizing, see the vCenter Server 4.x Database Sizing Calculator for Microsoft SQL
Server at http://www.vmware.com/support/vsphere4/doc/vsp_4x_db_calculator.xls.
View Connection Server Maximums and Virtual Machine Configuration
When you install View Connection Server, the View Administrator user interface is also installed. This server
requires more memory and processing resources than a vCenter Server instance.
View Connection Server Configuration
Although you can install View Connection Server on a physical machine, this example uses a virtual machine
with the specifications listed in Table 4-6. The ESX/ESXi host for this virtual machine can be part of a VMware
HA cluster to guard against physical server failures.
Table 4-6. Connection Server Virtual Machine Example
40
Item
Example
Operating system
64-bit Windows Server 2008 R2
RAM
10GB
Virtual CPU
4
System disk capacity
40GB
Virtual SCSI adapter type
LSI Logic SAS (the default for Windows Server 2008)
Virtual network adapter
E1000 (the default)
1 NIC
1 Gigabit
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View Connection Server Cluster Design Considerations
You can deploy multiple replicated View Connection Server instances in a group to support load balancing
and high availability. Groups of replicated instances are designed to support clustering within a LANconnected single-datacenter environment. VMware does not recommend using a group of replicated View
Connection Server instances across a WAN due to the communication traffic needed between the grouped
instances. In scenarios where a View deployment needs to span datacenters, create a separate View deployment
for each datacenter.
Maximum Connections for View Connection Server
Table 4-7 provides information about the tested limits regarding the number of simultaneous connections that
a VMware View deployment can accommodate.
This example assumes that you are using VMware View with vSphere 4.1 and vCenter Server 4.1. It also
assumes that View Connection Server is running on a 64-bit Windows Server 2008 R2 Enterprise operating
system.
Table 4-7. View Desktop Connections
Maximum Simultaneous
Connections
Connection Servers per Deployment
Connection Type
1 Connection Server
Direct connection, RDP or PCoIP;
Tunneled connection, RDP;
PCoIP Secure Gateway connection
2,000
7 Connection Servers (5 + 2 spares)
Direct connection, RDP or PCoIP
10,000
1 Connection Server
Unified Access to physical PCs
100
1 Connection Server
Unified Access to terminal servers
200
PCoIP Secure Gateway connections are required if you use security servers for PCoIP connections from outside
the corporate network. Tunneled connections are required if you use security servers for RDP connections
from outside the corporate network and for USB and multimedia redirection (MMR) acceleration with a PCoIP
Secure Gateway connection.
View Transfer Server Virtual Machine Configuration and Storage
View Transfer Server is required to support desktops that run View Client with Local Mode (formerly called
Offline Desktop). This server requires less memory than View Connection Server.
View Transfer Server Configuration
You must install View Transfer Server on a virtual rather than a physical machine and the virtual machine
must be managed by the same vCenter Server instance as the local desktops that it will manage. Table 4-8 lists
the virtual machine specifications for a View Transfer Server instance.
Table 4-8. View Transfer Server Virtual Machine Example
Item
Example
Operating system
64-bit Windows Server 2008 R2
RAM
4GB
Virtual CPU
2
System disk capacity
20GB
Virtual SCSI adapter type
LSI Logic Parallel (not the default, which is SAS)
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Table 4-8. View Transfer Server Virtual Machine Example (Continued)
Item
Example
Virtual network adapter
E1000 (the default)
1 NIC
1 Gigabit
Storage and Bandwidth Requirements for View Transfer Server
Several operations use View Transfer Server to send data between the View desktop in vCenter Server and the
corresponding local desktop on the client system. When a user checks in or checks out a desktop, View Transfer
Server transfers the files between the datacenter and the local desktop. View Transfer Server also synchronizes
local desktops with the corresponding desktops in the datacenter by replicating user-generated changes to the
datacenter.
If you use View Composer linked-clones for local desktops, the disk drive on which you configure the Transfer
Server repository must have enough space to store your static image files. Image files are View Composer base
images. The faster your network storage disks are, the better performance will be. For information about
determining the size of base image files, see the VMware View Administration document.
Each Transfer Server instance can theoretically accommodate 60 concurrent disk operations, although network
bandwidth will likely be saturated at a lower number. VMware tested 20 concurrent disk operations, such as
20 clients downloading a local desktop at the same time, over a 1GB per second network connection.
vSphere Clusters
VMware View deployments can use VMware HA clusters to guard against physical server failures. Because
of View Composer limitations, the cluster must contain no more than 8 servers, or nodes.
VMware vSphere and vCenter provide a rich set of features for managing clusters of servers that host View
desktops. The cluster configuration is also important because each View desktop pool must be associated with
a vCenter resource pool. Therefore, the maximum number of desktops per pool is related to the number of
servers and virtual machines that you plan to run per cluster.
In very large VMware View deployments, vCenter performance and responsiveness can be improved by
having only one cluster object per datacenter object, which is not the default behavior. By default, VMware
vCenter creates new clusters within the same datacenter object.
Determining Requirements for High Availability
VMware vSphere, through its efficiency and resource management, lets you achieve industry-leading levels
of virtual machines per server. But achieving a higher density of virtual machines per server means that more
users are affected if a server fails.
Requirements for high availability can differ substantially based on the purpose of the desktop pool. For
example, a stateless desktop image (floating-assignment) pool might have different recovery point objective
(RPO) requirements than a stateful desktop image (dedicated-assignment) pool. For a floating-assignment
pool, an acceptable solution might be to have users log in to a different desktop if the desktop they are using
becomes unavailable.
In cases where availability requirements are high, proper configuration of VMware HA is essential. If you use
VMware HA and are planning for a fixed number of desktops per server, run each server at a reduced capacity.
If a server fails, the capacity of desktops per server is not exceeded when the desktops are restarted on a different
host.
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For example, in an 8-host cluster, where each host is capable of running 128 desktops, and the goal is to tolerate
a single server failure, make sure that no more than 128 * (8 - 1) = 896 desktops are running on that cluster. You
can also use VMware DRS (Distributed Resource Scheduler) to help balance the desktops among all 8 hosts.
You get full use of the extra server capacity without letting any hot-spare resources sit idle. Additionally, DRS
can help rebalance the cluster after a failed server is restored to service.
You must also make sure that storage is properly configured to support the I/O load that results from many
virtual machines restarting at once in response to a server failure. Storage IOPS has the most effect on how
quickly desktops recover from a server failure.
Example: Cluster Configuration Example
The settings listed in Table 4-9 are VMware View-specific. For information about limits of HA clusters in
vSphere, see the VMware vSphere Configuration Maximums document.
Table 4-9. HA Cluster Example
Item
Example
Nodes (ESX servers)
8 (including 1 hot spare)
Cluster type
DRS (Distributed Resource Scheduler)/HA
Networking component
Standard ESX 4.1 cluster network
Switch ports
80
Networking requirements depend on the type of server, the number of network adapters, and the way in which
vMotion is configured.
VMware View Building Blocks
A 2,000-user building block consists of physical servers, a VMware vSphere infrastructure, VMware View
servers, shared storage, and 2,000 virtual machine desktops. You can include up to five building blocks in a
View pod.
Table 4-10. Example of a LAN-Based View Building Block
Item
Example
vSphere clusters
2 or more (with up to 8 ESX hosts in each cluster)
80-port network switch
1
Shared storage system
1
vCenter Server with View Composer
1 (can be run in the block itself)
Database
MS SQL Server or Oracle database server (can be run in the
block itself)
VLANs
3 (a 1Gbit Ethernet network for each: management network,
storage network, and VMotion network)
With vCenter 4.1, which has a limit of 10,000 virtual machines per vCenter, you might be able to use
vCenter Servers that manage virtual desktops in multiple building blocks. At the time this document was
written, VMware had not yet validated such an approach in conjunction with VMware View. Testing of
vCenter Server 4.1 with VMware View 4.5 and 4.6 was limited to testing 2,000 virtual desktops with one
vCenter Server.
If you have only one building block in a pod, use two View Connection Server instances for redundancy.
Figure 4-1 shows the components of a View building block.
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Figure 4-1. VMware View Building Block
2000 users
shared storage
8 hosts
8 hosts
2 VMware
ESX clusters
VMware
vCenter Server
Shared Storage for View Building Blocks
Storage design considerations are one of the most important elements of a successful View architecture. The
decision that has the greatest architectural impact is whether to use View Composer desktops, which use
linked-clone technology.
The external storage system that VMware vSphere uses can be a Fibre Channel or iSCSI SAN (storage area
network), or an NFS (Network File System) NAS (network-attached storage). The ESX binaries, virtual machine
swap files, and View Composer replicas of parent virtual machines are stored on this system.
From an architectural perspective, View Composer creates desktop images that share a base image, which can
reduce storage requirements by 50 percent or more. You can further reduce storage requirements by setting a
refresh policy that periodically returns the desktop to its original state and reclaims space that is used to track
changes since the last refresh operation.
You can also reduce operating system disk space by using View Composer persistent disks or a shared file
server as the primary repository for the user profile and user documents. Because View Composer lets you
separate user data from the operating system, you might find that only the persistent disk needs to be backed
up or replicated, which further reduces storage requirements. For more information, see “Reducing Storage
Requirements with View Composer,” on page 25.
NOTE Whether to use a separate, dedicated storage component for each building block is a decision you can
make during a pilot phase. The main consideration is I/Os per second (IOPS). You might experiment with a
tiered-storage strategy across multiple building blocks to maximize performance and cost savings.
For more information, see the best-practices guide called Storage Considerations for VMware View.
Storage Bandwidth Considerations
Although many elements are important to designing a storage system that supports a VMware View
environment, from a server configuration perspective, planning for proper storage bandwidth is essential. You
must also consider the effects of port consolidation hardware.
VMware View environments can occasionally experience I/O storm loads, during which all virtual machines
undertake an activity at the same time. I/O storms can be triggered by guest-based agents such as antivirus
software or software-update agents. I/O storms can also be triggered by human behavior, such as when all
employees log in at nearly the same time in the morning.
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You can minimize these storm workloads through operational best practices, such as staggering updates to
different virtual machines. You can also test various log-off policies during a pilot phase to determine whether
suspending or powering off virtual machines when users log off causes an I/O storm. By storing
View Composer replicas on separate, high-performance datastores, you can speed up intensive, concurrent
read operations to contend with I/O storm loads.
In addition to determining best practices, VMware recommends that you provide bandwidth of 1Gbps per 100
virtual machines, even though average bandwidth might be 10 times less than that. Such conservative planning
guarantees sufficient storage connectivity for peak loads.
Network Bandwidth Considerations
For display traffic, many elements can affect network bandwidth, such as protocol used, monitor resolution
and configuration, and the amount of multimedia content in the workload. Concurrent launches of streamed
applications can also cause usage spikes.
Because the effects of these issues can vary widely, many companies monitor bandwidth consumption as part
of a pilot project. As a starting point for a pilot, plan for 150 to 200Kbps of capacity for a typical knowledge
worker.
With the PCoIP display protocol, if you have an enterprise LAN with 100Mb or a 1Gb switched network, your
end users can expect excellent performance under the following conditions:
n
Two monitors (1920x1080)
n
Heavy use of Microsoft Office applications
n
Heavy use of Flash-embedded Web browsing
n
Frequent use of multimedia with limited use of full screen mode
n
Frequent use of USB-based peripherals
n
Network-based printing
This information was excerpted from the information guide called PCoIP Display Protocol: Information and
Scenario-Based Network Sizing Guide.
WAN Support and PCoIP
For wide-area networks (WANs), you must consider bandwidth constraints and latency issues. The PCoIP
display protocol provided by VMware adapts to varying latency and bandwidth conditions.
If you use the RDP display protocol, you must have a WAN optimization product to accelerate applications
for users in branch offices or small offices. With PCoIP, many WAN optimization techniques are built into the
base protocol.
n
WAN optimization is valuable for TCP-based protocols such as RDP because these protocols require many
handshakes between client and server. The latency of these handshakes can be quite large. WAN
accelerators spoof replies to handshakes so that the latency of the network is hidden from the protocol.
Because PCoIP is UDP-based, this form of WAN acceleration is unnecessary.
n
WAN accelerators also compress network traffic between client and server, but this compression is usually
limited to 2:1 compression ratios. PCoIP is able to provide compression ratios of up to 100:1 for images
and audio.
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The following examples show how PCoIP can be expected to perform in various WAN scenarios:
Work from home
Mobile user
A user with a dedicated cable or DSL connection with 4-8MB download and
less than 300ms latency can expect excellent performance under the following
conditions:
n
Two monitors (1920x1080)
n
Microsoft Office applications
n
Light use of Flash-embedded Web browsing
n
Periodic use of multimedia
n
Light printing with a locally connected USB printer
A user with a dedicated 3G connection with 5-500Kb download and less than
300ms latency can expect adequate bandwidth and tolerable latency under the
following conditions:
n
Single monitor
n
Microsoft Office applications
n
Light use of Flash-embedded Web browsing
n
Light printing with a locally connected USB printer
Encourage mobile users to use local applications to access multimedia content.
Branch or remote office
Plan for 3 concurrent active users per 1Mb of bandwidth. Users at an office that
has a 20Mb dedicated site-to-site UDP-based VPN with less than 200ms latency
can expect acceptable performance under the following conditions:
n
Two monitors (1920x1080)
n
Microsoft Office applications
n
Light use of Flash-embedded Web browsing
n
Light printing with a locally connected USB printer
This information was excerpted from the information guide called PCoIP Display Protocol: Information and
Scenario-Based Network Sizing Guide.
For information about setting up VPNs for using PCoIP, see the following solutions overviews, available on
the VMware Web site:
n
VMware View and Juniper Networks SA Servers SSL VPN Solution
n
VMware View and F5 BIG-IP SSL VPN Solution
n
VMware View and Cisco Adaptive Security Appliances (ASA) SSL VPN Solution
VMware View Pod
A VMware View pod integrates five 2,000-user building blocks into a View Manager installation that you can
manage as one entity.
A pod is a unit of organization determined by VMware View scalability limits. Table 4-11 lists the components
of a View pod.
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Table 4-11. Example of a VMware View Pod
Item
Number
View building blocks
5
View Connection Servers
7 (1 for each building block and 2 spares)
10Gb Ethernet module
1
Modular networking switch
1
Load-balancing module
1
VPN for WAN
1 (optional)
The network core load balances incoming requests across View Connection Server instances. Support for a
redundancy and failover mechanism, usually at the network level, prevents the load balancer from becoming
a single point of failure. For example, the Virtual Router Redundancy Protocol (VRRP) communicates with the
load balancer to add redundancy and failover capability.
If a View Connection Server instance fails or becomes unresponsive during an active session, users do not lose
data. Desktop states are preserved in the virtual machine desktop so that users can connect to a different View
Connection Server instance and their desktop session resumes from where it was when the failure occurred.
Figure 4-2 shows how all the components can be integrated into one manageable entity.
Figure 4-2. Pod Diagram for 10,000 View Desktops
VMware View
building blocks
switched networks
Each switched network connects to each View Connection Server
VMware View
Connection Servers
load balancing
network core
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Planning for Security Features
5
VMware View offers strong network security to protect sensitive corporate data. For added security, you can
integrate VMware View with certain third-party user-authentication solutions, use a security server, and
implement the restricted entitlements feature.
This chapter includes the following topics:
n
“Understanding Client Connections,” on page 49
n
“Choosing a User Authentication Method,” on page 52
n
“Restricting View Desktop Access,” on page 55
n
“Using Group Policy Settings to Secure View Desktops,” on page 56
n
“Implementing Best Practices to Secure Client Systems,” on page 56
n
“Assigning Administrator Roles,” on page 56
n
“Preparing to Use a Security Server,” on page 57
n
“Understanding VMware View Communications Protocols,” on page 61
Understanding Client Connections
View Client and View Administrator communicate with a View Connection Server host over secure HTTPS
connections.
The initial View Client connection, which is used for user authentication and View desktop selection, is created
when a user opens View Client and provides an IP address or domain name for the View Connection Server
or security server host. The View Administrator connection is created when an administrator types the View
Administrator URL into a Web browser.
A default server SSL certificate is generated during View Connection Server installation. By default, clients are
presented with this certificate when they visit a secure page such as View Administrator.
You can use the default certificate for testing, but you should replace it with your own certificate as soon as
possible. The default certificate is not signed by a commercial Certificate Authority (CA). Use of noncertified
certificates can allow untrusted parties to intercept traffic by masquerading as your server.
n
Client Connections Using the PCoIP Secure Gateway on page 50
When clients connect to a View desktop with the PCoIP display protocol from VMware, View Client can
make a second connection to the PCoIP Secure Gateway component on a View Connection Server
instance or a security server. This connection provides the required level of security and connectivity
when accessing View desktops from the Internet.
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n
Tunneled Client Connections with Microsoft RDP on page 51
When users connect to a View desktop with the Microsoft RDP display protocol, View Client can make
a second HTTPS connection to the View Connection Server host. This connection is called the tunnel
connection because it provides a tunnel for carrying RDP data.
n
Direct Client Connections on page 51
Administrators can configure View Connection Server settings so that View desktop sessions are
established directly between the client system and the View desktop virtual machine, bypassing the View
Connection Server host. This type of connection is called a direct client connection.
n
View Client with Local Mode Client Connections on page 52
View Client with Local Mode offers mobile users the ability to check out View desktops onto their local
computer.
Client Connections Using the PCoIP Secure Gateway
When clients connect to a View desktop with the PCoIP display protocol from VMware, View Client can make
a second connection to the PCoIP Secure Gateway component on a View Connection Server instance or a
security server. This connection provides the required level of security and connectivity when accessing View
desktops from the Internet.
As of View 4.6, security servers include a PCoIP Secure Gateway component. The PCoIP Secure Gateway
connection offers the following advantages:
n
The only remote desktop traffic that can enter the corporate data center is traffic on behalf of a strongly
authenticated user.
n
Users can access only the desktop resources that they are authorized to access.
n
This connection supports PCoIP, which is an advanced remote desktop protocol that makes more efficient
use of the network by encapsulating video display packets in UDP instead of TCP.
n
PCoIP is secured by AES-128 encryption.
n
No VPN is required, as long as PCoIP is not blocked by any networking component. For example, someone
trying to access their View desktop from inside a hotel room might find that the proxy the hotel uses is
not configured to allow inbound traffic on TCP port 4172 and both inbound and outbound traffic on UDP
port 4172.
For more information, see “Firewall Rules for DMZ-Based Security Servers,” on page 60.
Security servers with PCoIP support run on Windows Server 2008 R2 and take full advantage of the 64-bit
architecture. This security server can also take advantage of Intel processors that support AES New Instructions
(AESNI) for highly optimized PCoIP encryption and decryption performance.
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Tunneled Client Connections with Microsoft RDP
When users connect to a View desktop with the Microsoft RDP display protocol, View Client can make a second
HTTPS connection to the View Connection Server host. This connection is called the tunnel connection because
it provides a tunnel for carrying RDP data.
The tunnel connection offers the following advantages:
n
RDP data is tunneled through HTTPS and is encrypted using SSL. This powerful security protocol is
consistent with the security provided by other secure Web sites, such as those that are used for online
banking and credit card payments.
n
A client can access multiple desktops over a single HTTPS connection, which reduces the overall protocol
overhead.
n
Because VMware View manages the HTTPS connection, the reliability of the underlying protocols is
significantly improved. If a user temporarily loses a network connection, the HTTP connection is
reestablished after the network connection is restored and the RDP connection automatically resumes
without requiring the user to reconnect and log in again.
In a standard deployment of View Connection Server instances, the HTTPS secure connection terminates at
the View Connection Server. In a DMZ deployment, the HTTPS secure connection terminates at a security
server. See “Preparing to Use a Security Server,” on page 57 for information on DMZ deployments and
security servers.
Clients that use the PCoIP display protocol can use the tunnel connection for USB redirection and multimedia
redirection (MMR) acceleration, but for all other data, PCoIP uses the PCoIP Secure Gateway on a security
server. For more information, see “Client Connections Using the PCoIP Secure Gateway,” on page 50.
Clients that use the PCoIP or HP RGS display protocols do not use the tunnel connection.
Direct Client Connections
Administrators can configure View Connection Server settings so that View desktop sessions are established
directly between the client system and the View desktop virtual machine, bypassing the View Connection
Server host. This type of connection is called a direct client connection.
With direct client connections, an HTTPS connection can still be made between the client and the View
Connection Server host for users to authenticate and select View desktops, but the second HTTPS connection
(the tunnel connection) is not used.
Clients that use the HP RGS display protocol always use direct client connections. HP RGS clients cannot use
a tunnel connection or a PCoIP Secure Gateway connection.
Direct PCoIP connections include the following built-in security features:
n
PCoIP supports Advanced Encryption Standard (AES) encryption, which is turned on by default.
n
The hardware implementation of PCoIP uses both AES and IP Security (IPsec).
n
PCoIP works with third-party VPN clients.
For clients that use the Microsoft RDP display protocol, direct client connections are appropriate only if your
deployment is inside a corporate network. With direct client connections, RDP traffic is sent unencrypted over
the connection between the client and the View desktop virtual machine.
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View Client with Local Mode Client Connections
View Client with Local Mode offers mobile users the ability to check out View desktops onto their local
computer.
View Client with Local Mode supports both tunneled and nontunneled communications for LAN-based data
transfers. With tunneled communications, all traffic is routed through the View Connection Server host, and
you can specify whether to encrypt communications and data transfers. With nontunneled communications,
unencrypted data is transferred directly between the local desktop on the client system and the View desktop
virtual machine in vCenter Server.
Local data is always encrypted on the user's computer, regardless of whether you configure tunneled or
nontunneled communications.
The data disk stored locally on client systems is encrypted using a default encryption strength of AES-128. The
encryption keys are stored encrypted on the client system with a key derived from a hash of the user's
credentials (username and password or smart card and PIN). On the server side, the key is stored in View
LDAP. Whatever security measures you use to protect View LDAP on the server also protect the local mode
encryption keys stored in LDAP.
NOTE You can change the encryption key cipher from AES-128 to AES-192 or AES-256.
The desktop has a lifetime controlled through policy. If the client loses contact with View Connection Server,
the maximum time without server contact is the period in which the user can continue to use the desktop before
the user is refused access. On the client side, this expiration policy is stored in a file that is encrypted by a key
that is built into the application. This built-in key prevents users who have access to the password from
circumventing the expiration policy.
Choosing a User Authentication Method
VMware View uses your existing Active Directory infrastructure for user authentication and management.
For added security, you can integrate VMware View with RSA SecurID and smart card authentication
solutions.
n
Active Directory Authentication on page 53
Each View Connection Server instance is joined to an Active Directory domain, and users are
authenticated against Active Directory for the joined domain. Users are also authenticated against any
additional user domains with which a trust agreement exists.
n
RSA SecurID Authentication on page 53
RSA SecurID provides enhanced security with two-factor authentication, which requires knowledge of
the user's PIN and token code. The token code is only available on the physical SecurID token.
n
Smart Card Authentication on page 53
A smart card is a small plastic card that is embedded with a computer chip. Many government agencies
and large enterprises use smart cards to authenticate users who access their computer networks. A smart
card is also referred to as a Common Access Card (CAC).
n
Log In as Current User Feature on page 54
When View Client users select the Log in as current user check box, the credentials that they provided
when logging in to the client system are used to authenticate to the View Connection Server instance and
to the View desktop. No further user authentication is required.
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Active Directory Authentication
Each View Connection Server instance is joined to an Active Directory domain, and users are authenticated
against Active Directory for the joined domain. Users are also authenticated against any additional user
domains with which a trust agreement exists.
For example, if a View Connection Server instance is a member of Domain A and a trust agreement exists
between Domain A and Domain B, users from both Domain A and Domain B can connect to the View
Connection Server instance with View Client.
Similarly, if a trust agreement exists between Domain A and an MIT Kerberos realm in a mixed domain
environment, users from the Kerberos realm can select the Kerberos realm name when connecting to the View
Connection Server instance with View Client.
View Connection Server determines which domains are accessible by traversing trust relationships, starting
with the domain in which the host resides. For a small, well-connected set of domains, View Connection Server
can quickly determine a full list of domains, but the time that it takes increases as the number of domains
increases or as the connectivity between the domains decreases. The list might also include domains that you
would prefer not to offer to users when they log in to their desktops.
Administrators can use the vdmadmin command-line interface to configure domain filtering, which limits the
domains that a View Connection Server instance searches and that it displays to users. See the VMware View
Administration document for more information.
Policies, such as restricting permitted hours to log in and setting the expiration date for passwords, are also
handled through existing Active Directory operational procedures.
RSA SecurID Authentication
RSA SecurID provides enhanced security with two-factor authentication, which requires knowledge of the
user's PIN and token code. The token code is only available on the physical SecurID token.
Administrators can enable individual View Connection Server instances for RSA SecurID authentication by
installing the RSA SecurID software on the View Connection Server host and modifying View Connection
Server settings.
When users log in through a View Connection Server instance that is enabled for RSA SecurID authentication,
they are first required to authenticate with their RSA user name and passcode. If they are not authenticated at
this level, access is denied. If they are correctly authenticated with RSA SecurID, they continue as normal and
are then required to enter their Active Directory credentials.
If you have multiple View Connection Server instances, you can configure RSA SecurID authentication on
some instances and a different user authentication method on others. For example, you can configure RSA
SecurID authentication only for users who access View desktops remotely over the Internet.
VMware View is certified through the RSA SecurID Ready program and supports the full range of SecurID
capabilities, including New PIN Mode, Next Token Code Mode, RSA Authentication Manager, and load
balancing.
Smart Card Authentication
A smart card is a small plastic card that is embedded with a computer chip. Many government agencies and
large enterprises use smart cards to authenticate users who access their computer networks. A smart card is
also referred to as a Common Access Card (CAC).
Smart card authentication is supported by the Windows-based View Client and View Client with Local Mode
only. It is not supported by View Administrator.
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Administrators can enable individual View Connection Server instances for smart card authentication.
Enabling a View Connection Server instance to use smart card authentication typically involves adding your
root certificate to a truststore file and then modifying View Connection Server settings.
Client connections that use smart card authentication must be SSL enabled. Administrators can enable SSL for
client connections by setting a global parameter in View Administrator.
To use smart cards, client machines must have smart card middleware and a smart card reader. To install
certificates on smart cards, you must set up a computer to act as an enrollment station.
To use smart cards with local desktops, you must select a 1024-bit or 2048-bit key size during smart card
enrollment. Certificates with 512-bit keys are not supported for local desktops. By default, View Connection
Server uses AES-128 to encrypt the virtual disk file when users check in and check out a local desktop. You
can change the encryption key cipher to AES-192 or AES-256.
Log In as Current User Feature
When View Client users select the Log in as current user check box, the credentials that they provided when
logging in to the client system are used to authenticate to the View Connection Server instance and to the View
desktop. No further user authentication is required.
To support this feature, user credentials are stored on both the View Connection Server instance and on the
client system.
n
On the View Connection Server instance, user credentials are encrypted and stored in the user session
along with the username, domain, and optional UPN. The credentials are added when authentication
occurs and are purged when the session object is destroyed. The session object is destroyed when the user
logs out, the session times out, or authentication fails. The session object resides in volatile memory and
is not stored in View LDAP or in a disk file.
n
On the client system, user credentials are encrypted and stored in a table in the Authentication Package,
which is a component of View Client. The credentials are added to the table when the user logs in and are
removed from the table when the user logs out. The table resides in volatile memory.
Administrators can use View Client group policy settings to control the availability of the Log in as current
user check box and to specify its default value. Administrators can also use group policy to specify which View
Connection Server instances accept the user identity and credential information that is passed when users
select the Log in as current user check box in View Client.
The Log in as current user feature has the following limitations and requirements:
54
n
If smart card authentication is set to Required on a View Connection Server instance, smart card users
who select the Log in as current user check box must still reauthenticate with their smart card and PIN
when logging in to the View desktop.
n
Users cannot check out a desktop for use in local mode if they selected the Log in as current user check
box when they logged in.
n
The time on the system where the client logs in and the time on the View Connection Server host must be
synchronized.
n
If the default Access this computer from the network user-right assignments are modified on the client
system, they must be modified as described in VMware Knowledge Base (KB) article 1025691.
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Restricting View Desktop Access
You can use the restricted entitlements feature to restrict View desktop access based on the View Connection
Server instance that a user connects to.
With restricted entitlements, you assign one or more tags to a View Connection Server instance. Then, when
configuring a desktop pool, you select the tags of the View Connection Server instances that you want to be
able to access the desktop pool. When users log in through a tagged View Connection Server instance, they
can access only those desktop pools that have at least one matching tag or no tags.
For example, your VMware View deployment might include two View Connection Server instances. The first
instance supports your internal users. The second instance is paired with a security server and supports your
external users. To prevent external users from accessing certain desktops, you could set up restricted
entitlements as follows:
n
Assign the tag "Internal" to the View Connection Server instance that supports your internal users.
n
Assign the tag "External" to the View Connection Server instance that is paired with the security server
and supports your external users.
n
Assign the "Internal" tag to the desktop pools that should be accessible only to internal users.
n
Assign the "External" tag to the desktop pools that should be accessible only to external users.
External users cannot see the desktop pools tagged as Internal because they log in through the View Connection
Server tagged as External, and internal users cannot see the desktop pools tagged as External because they log
in through the View Connection Server tagged as Internal. Figure 5-1 illustrates this configuration.
Figure 5-1. Restricted Entitlements Example
remote
View Client
external network
DMZ
View
Security
Server
local
View Client
View
Connection
Server
Tag: “External”
View
Connection
Server
Tag: “Internal”
VM
VM
VM
VM
VM
VM
VM
VM
desktop pool A
Tag: “External”
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desktop pool B
Tag: “Internal”
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You can also use restricted entitlements to control desktop access based on the user-authentication method
that you configure for a particular View Connection Server instance. For example, you can make certain
desktop pools available only to users who have authenticated with a smart card.
The restricted entitlements feature only enforces tag matching. You must design your network topology to
force certain clients to connect through a particular View Connection Server instance.
Using Group Policy Settings to Secure View Desktops
VMware View includes Group Policy administrative (ADM) templates that contain security-related group
policy settings that you can use to secure your View desktops.
For example, you can use group policy settings to perform the following tasks.
n
Specify the View Connection Server instances that can accept user identity and credential information that
is passed when a user selects the Log in as current user check box in View Client.
n
Enable single sign-on for smart card authentication in View Client.
n
Configure server SSL certificate checking in View Client.
n
Prevent users from providing credential information with View Client command line options.
n
Prevent non-View client systems from using RDP to connect to View desktops. You can set this policy so
that connections must be View-managed, which means that users must use View Client to connect to View
desktops.
See the VMware View Administration document for information on using View Client group policy settings.
Implementing Best Practices to Secure Client Systems
You should implement best practices to secure client systems.
n
Make sure that client systems are configured to go to sleep after a period of inactivity and require users
to enter a password before the computer awakens.
n
Require users to enter a username and password when starting client systems. Do not configure client
systems to allow automatic logins.
n
For Mac client systems, consider setting different passwords for the Keychain and the user account. When
the passwords are different, users are prompted before the system enters any passwords on their behalf.
Also consider turning on FileVault protection.
n
Local mode client systems might have more network access when they are running in local mode than
when they are remote and connected to the intranet. Consider enforcing intranet network security policies
for local mode client systems or disable network access for local mode client systems when they are
running in local mode.
Assigning Administrator Roles
A key management task in a VMware View environment is to determine who can use View Administrator and
what tasks those users are authorized to perform.
The authorization to perform tasks in View Administrator is governed by an access control system that consists
of administrator roles and privileges. A role is a collection of privileges. Privileges grant the ability to perform
specific actions, such as entitling a user to a desktop pool or changing a configuration setting. Privileges also
control what an administrator can see in View Administrator.
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An administrator can create folders to subdivide desktop pools and delegate the administration of specific
desktop pools to different administrators in View Administrator. An administrator configures administrator
access to the resources in a folder by assigning a role to a user on that folder. Administrators can only access
the resources that reside in folders for which they have assigned roles. The role that an administrator has on
a folder determines the level of access that the administrator has to the resources in that folder.
View Administrator includes a set of predefined roles. Administrators can also create custom roles by
combining selected privileges.
Preparing to Use a Security Server
A security server is a special instance of View Connection Server that runs a subset of View Connection Server
functions. You can use a security server to provide an additional layer of security between the Internet and
your internal network.
A security server resides within a DMZ and acts as a proxy host for connections inside your trusted network.
Each security server is paired with an instance of View Connection Server and forwards all traffic to that
instance. This design provides an additional layer of security by shielding the View Connection Server instance
from the public-facing Internet and by forcing all unprotected session requests through the security server.
A DMZ-based security server deployment requires a few ports to be opened on the firewall to allow clients to
connect with security servers inside the DMZ. You must also configure ports for communication between
security servers and the View Connection Server instances in the internal network. See “Firewall Rules for
DMZ-Based Security Servers,” on page 60 for information on specific ports.
Because users can connect directly with any View Connection Server instance from within their internal
network, you do not need to implement a security server in a LAN-based deployment.
NOTE As of View 4.6, security servers include a PCoIP Secure Gateway component so that clients that use the
PCoIP display protocol can use a security server rather than a VPN.
For information about setting up VPNs for using PCoIP, see the following solutions overviews, available on
the VMware Web site:
n
VMware View and Juniper Networks SA Servers SSL VPN Solution
n
VMware View and F5 BIG-IP SSL VPN Solution
n
VMware View and Cisco Adaptive Security Appliances (ASA) SSL VPN Solution
Best Practices for Security Server Deployments
You should follow best practice security policies and procedures when operating a security server in a DMZ.
The DMZ Virtualization with VMware Infrastructure white paper includes examples of best practices for a
virtualized DMZ. Many of the recommendations in this white paper also apply to a physical DMZ.
To limit the scope of frame broadcasts, the View Connection Server instances that are paired with security
servers should be deployed on an isolated network. This topology can help prevent a malicious user on the
internal network from monitoring communication between the security servers and View Connection Server
instances.
Alternatively, you might be able to use advanced security features on your network switch to prevent malicious
monitoring of security server and View Connection Server communication and to guard against monitoring
attacks such as ARP Cache Poisoning. See the administration documentation for your networking equipment
for more information.
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Security Server Topologies
You can implement several different security server topologies.
The topology illustrated in Figure 5-2 shows a high-availability environment that includes two load-balanced
security servers in a DMZ. The security servers communicate with two View Connection Server instances
inside the internal network.
Figure 5-2. Load-Balanced Security Servers in a DMZ
remote
View Client
external network
DMZ
load balancing
View
Security
Servers
View
Connection
Servers
Microsoft
Active Directory
vCenter
Management Server
ESX hosts running
Virtual Desktop
virtual machines
When remote users connect to a security server, they must successfully authenticate before they can access
View desktops. With appropriate firewall rules on both sides of the DMZ, this topology is suitable for accessing
View desktops from client devices located on the Internet.
You can connect multiple security servers to each instance of View Connection Server. You can also combine
a DMZ deployment with a standard deployment to offer access for internal users and external users.
The topology illustrated in Figure 5-3 shows an environment where four instances of View Connection Server
act as one group. The instances in the internal network are dedicated to users of the internal network, and the
instances in the external network are dedicated to users of the external network. If the View Connection Server
instances paired with the security servers are enabled for RSA SecurID authentication, all external network
users are required to authenticate by using RSA SecurID tokens.
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Chapter 5 Planning for Security Features
Figure 5-3. Multiple Security Servers
remote
View Client
external network
View Client
internal network
DMZ
load balancing
View
Security
Servers
load balancing
View
Connection
Servers
vCenter
Management Server
Microsoft
Active Directory
ESX hosts running
Virtual Desktop
virtual machines
You must implement a hardware or software load balancing solution if you install more than one security
server. View Connection Server does not provide its own load balancing functionality. View Connection Server
works with standard third-party load balancing solutions.
Firewalls for DMZ-Based Security Servers
A DMZ-based security server deployment must include two firewalls.
n
An external network-facing, front-end firewall is required to protect both the DMZ and the internal
network. You configure this firewall to allow external network traffic to reach the DMZ.
n
A back-end firewall, between the DMZ and the internal network, is required to provide a second tier of
security. You configure this firewall to accept only traffic that originates from the services within the DMZ.
Firewall policy strictly controls inbound communications from DMZ services, which greatly reduces the risk
of compromising your internal network.
Figure 5-4 shows an example of a configuration that includes front-end and back-end firewalls.
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Figure 5-4. Dual Firewall Topology
View Client
View Client
HTTPS
traffic
front-end
firewall
fault-tolerant
load balancing
mechanism
HTTPS
traffic
DMZ
View
Security
Server
View
Security
Server
back-end
firewall
internal
network
View
Connection
Server
View
Connection
Server
VMware
vCenter
Active
Directory
VMware
ESX servers
Firewall Rules for DMZ-Based Security Servers
DMZ-based security servers require certain firewall rules on the front-end and back-end firewalls.
Front-End Firewall Rules
To allow external client devices to connect to a security server within the DMZ, the front-end firewall must
allow traffic on certain TCP and UDP ports. Table 5-1 summarizes the front-end firewall rules.
Table 5-1. Front-End Firewall Rules
60
Source
Protocol
Port
Destination
Notes
Any
HTTP
80
Security server
External client devices use port 80 to connect to a
security server within the DMZ when SSL is
disabled.
Any
HTTPS
443
Security server
External client devices use port 443 to connect to a
security server within the DMZ when SSL is
enabled (the default).
Any
PCoIP
TCP 4172
UDP 4172
Security server
External client devices use TCP port 4172 to a
security server within the DMZ when SSL is
enabled and also use UDP port 4172 in both
directions.
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Chapter 5 Planning for Security Features
Back-End Firewall Rules
To allow a security server to communicate with each View Connection Server instance that resides within the
internal network, the back-end firewall must allow inbound traffic on certain TCP ports. Behind the back-end
firewall, internal firewalls must be similarly configured to allow View desktops and View Connection Server
instances to communicate with each other. Table 5-2 summarizes the back-end firewall rules.
Table 5-2. Back-End Firewall Rules
Source
Protocol
Port
Destination
Notes
Security server
HTTP
80
Transfer Server
Security servers can use port 80 to
download View desktop data to local
mode desktops from the Transfer Server
and to replicate data to the Transfer
Server.
Security server
HTTPS
443
Transfer Server
If you configure View Connection
Server to use SSL for local mode
operations and desktop provisioning,
security servers use port 443 for
downloads and replication between
local mode desktops and the Transfer
Server.
Security server
AJP13
8009
View Connection Server
Security servers use port 8009 to
transmit AJP13-forwarded Web traffic
to View Connection Server instances.
Security server
JMS
4001
View Connection Server
Security servers use port 4001 to
transmit Java Message Service (JMS)
traffic to View Connection Server
instances.
Security server
RDP
3389
View desktop
Security servers use port 3389 to
transmit RDP traffic to View desktops.
NOTE For USB redirection, TCP port
32111 is used alongside RDP. For MMR,
TCP port 9427 is used alongside RDP.
Security server
PCoIP
TCP 4172
UDP
4172
View desktop
Security servers use TCP port 4172 to
transmit PCoIP traffic to View desktops,
and security servers use UDP port 4172
to transmit PCoIP traffic in both
directions.
For USB redirection, TCP port 32111 is
used alongside PCoIP from the client to
the View desktop.
TCP Ports for View Connection Server Intercommunication
Groups of View Connection Server instances use additional TCP ports to communicate with each other. For
example, View Connection Server instances use port 4100 to transmit JMS inter-router (JMSIR) traffic to each
other. Firewalls are generally not used between the View Connection Server instances in a group.
Understanding VMware View Communications Protocols
VMware View components exchange messages by using several different protocols.
Figure 5-5 illustrates the protocols that each component uses for communication when a security server is not
configured. That is, the secure tunnel for RDP and the PCoIP secure gateway are not turned on. This
configuration might be used in a typical LAN deployment.
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Figure 5-5. VMware View Components and Protocols Without a Security Server
Mac, Windows, and Linux Clients
RDP
Client
Thin Client
thin client
operating system
View Client
PCoIP
RDP
PCoIP
HTTP(S)
HTTP(S)
View
Administrator
View Secure
GW Server & PCoIP
Secure GW
View
Connection
Server
View
Messaging
RDP
HTTP(S)
View Broker &
Admin Server
SOAP
vCenter
Server
View Manager
LDAP
JMS
RDP
PCoIP
RDP
View Agent
PCoIP
View desktop
virtual machine
NOTE This figure shows direct connections for clients using either PCoIP or RDP. The default setting, however,
is to have direct connections for PCoIP and tunnel connections for RDP.
See Table 5-3 for the default ports that are used for each protocol.
Figure 5-6 illustrates the protocols that each component uses for communication when a security server is
configured. This configuration might be used in a typical WAN deployment.
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Chapter 5 Planning for Security Features
Figure 5-6. VMware View Components and Protocols with a Security Server
Mac, Windows, and Linux Clients
RDP
Client
Thin Client
thin client
operating system
View Client
HTTP(S)
HTTP(S)
HTTP(S)
HTTP(S)
HTTP(S)
View
Security
Server
RDP
View Secure
GW Server & PCoIP
Secure GW
PCoIP
PCoIP
RDP
JMS
AJP13
View
Administrator
View Secure
GW Server & PCoIP
Secure GW
View
Connection
Server
View
Messaging
HTTP(S)
View Broker &
Admin Server
SOAP
vCenter
Server
View Manager
LDAP
JMS
RDP
PCoIP
RDP
PCoIP
View Agent
View desktop
virtual machine
Table 5-3 lists the default ports that are used by each protocol.
Table 5-3. Default Ports
Protocol
Port
JMS
TCP port 4001
AJP13
TCP port 8009
NOTE AJP13 is used in a security server configuration only.
HTTP
TCP port 80
HTTPS
TCP port 443
RDP
TCP port 3389
For USB redirection, TCP port 32111 is used alongside RDP.
For MMR, TCP port 9427 is used alongside RDP.
NOTE If the View Connection Server instance is configured
for direct client connections, these protocols connect directly
from the client to the View desktop and are not tunneled
through the View Secure GW Server component.
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Table 5-3. Default Ports (Continued)
Protocol
Port
SOAP
TCP port 80 or 443
PCoIP
TCP port 4172 from View Client to the View desktop.
PCoIP also uses UDP port 4172 in both directions.
For USB redirection, TCP port 32111 is used alongside PCoIP
from the client to the View desktop.
View Broker and Administration Server
The View Broker component, which is the core of View Connection Server, is responsible for all user interaction
between VMware View clients and View Connection Server. View Broker also includes the Administration
Server that is used by the View Administrator Web client.
View Broker works closely with vCenter Server to provide advanced management of View desktops, including
virtual machine creation and power operations.
View Secure Gateway Server
View Secure Gateway Server is the server-side component for the secure HTTPS connection between VMware
View clients and a security server or View Connection Server instance.
When you configure the tunnel connection for View Connection Server, RDP, USB, and Multimedia
Redirection (MMR) traffic is tunneled through the View Secure Gateway component. When you configure
direct client connections, these protocols connect directly from the client to the View desktop and are not
tunneled through the View Secure Gateway Server component.
NOTE Clients that use the PCoIP display protocol can use the tunnel connection for USB redirection and
multimedia redirection (MMR) acceleration, but for all other data, PCoIP uses the PCoIP Secure Gateway on
a security server.
HP RGS does not use the tunnel connection at all.
View Secure Gateway Server is also responsible for forwarding other Web traffic, including user authentication
and desktop selection traffic, from VMware View clients to the View Broker component. View Secure Gateway
Server also passes View Administrator client Web traffic to the Administration Server component.
PCoIP Secure Gateway
As of View 4.6, security servers include a PCoIP Secure Gateway component. When the PCoIP Secure Gateway
is enabled, after authentication, View clients that use PCoIP can make another secure connection to a security
server. This connection allows remote clients to access View desktops from the Internet.
When you enable the PCoIP Secure Gateway component, PCoIP traffic is forwarded by a security server to
View desktops. If clients that use PCoIP also use the USB redirection feature or multimedia redirection (MMR)
acceleration, you can enable the View Secure Gateway component in order to forward that data.
When you configure direct client connections, PCoIP traffic and other traffic goes directly from a View client
to a View desktop.
When end users such as home or mobile workers access desktops from the Internet, security servers provide
the required level of security and connectivity so that a VPN connection is not necessary. The PCoIP Secure
Gateway component ensures that the only remote desktop traffic that can enter the corporate data center is
traffic on behalf of a strongly authenticated user. End users can access only the desktop resources that they are
authorized to access.
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Chapter 5 Planning for Security Features
View LDAP
View LDAP is an embedded LDAP directory in View Connection Server and is the configuration repository
for all VMware View configuration data.
View LDAP contains entries that represent each View desktop, each accessible View desktop, multiple View
desktops that are managed together, and View component configuration settings.
View LDAP also includes a set of View plug-in DLLs to provide automation and notification services for other
VMware View components.
View Messaging
The View Messaging component provides the messaging router for communication between View Connection
Server components and between View Agent and View Connection Server.
This component supports the Java Message Service (JMS) API, which is used for messaging in VMware View.
By default, RSA keys that are used for intercomponent message validation are 512 bits. The RSA key size can
be increased to 1024 bits if you prefer stronger encryption.
If you want all keys to be 1024 bits, the RSA key size must be changed immediately after the first View
Connection Server instance is installed and before additional servers and desktops are created. See VMware
Knowledge Base (KB) article 1024431 for more information.
Firewall Rules for View Connection Server
Certain ports must be opened on the firewall for View Connection Server instances and security servers.
When you install View Connection Server on Windows Server 2008, the installation program can optionally
configure the required Windows firewall rules for you. When you install View Connection Server on Windows
Server 2003, you must configure the required Windows firewall rules manually.
Table 5-4. Ports Opened During View Connection Server Installation
Protocol
Ports
View Connection Server Instance Type
JMS
TCP 4001 in
Standard and replica
JMSIR
TCP 4100 in
Standard and replica
AJP13
TCP 8009 in
Standard and replica
HTTP
TCP 80 in
Standard, replica, and security server
HTTPS
TCP 443 in
Standard, replica, and security server
PCoIP
TCP 4172 in;
UDP 4172 both
directions
Standard, replica, and security server
Firewall Rules for View Agent
The View Agent installation program opens certain TCP ports on the firewall. Ports are incoming unless
otherwise noted.
Table 5-5. TCP Ports Opened During View Agent Installation
Protocol
Ports
RDP
3389
USB redirection
32111
MMR
9427
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Table 5-5. TCP Ports Opened During View Agent Installation (Continued)
Protocol
Ports
PCoIP
4172 (TCP and UDP)
HP RGS
42966
The View Agent installation program configures the local firewall rule for inbound RDP connections to match
the current RDP port of the host operating system, which is typically 3389. If you change the RDP port number,
you must change the associated firewall rules.
If you instruct the View Agent installation program to not enable Remote Desktop support, it does not open
ports 3389 and 32111, and you must open these ports manually.
The HP RGS Sender application is the server-side component of the HP RGS remote display protocol. HP RGS
Sender uses port 42966 by default.
If you use a virtual machine template as a desktop source, firewall exceptions carry over to deployed desktops
only if the template is a member of the desktop domain. You can use Microsoft group policy settings to manage
local firewall exceptions. See the Microsoft Knowledge Base (KB) article 875357 for more information.
Firewall Rules for Active Directory
If you have a firewall between your VMware View environment and your Active Directory server, you must
make sure that all of the necessary ports are opened.
For example, View Connection Server must be able to access the Active Directory Global Catalog and
Lightweight Directory Access Protocol (LDAP) servers. If the Global Catalog and LDAP ports are blocked by
your firewall software, administrators will have problems configuring user entitlements.
See the Microsoft documentation for your Active Directory server version for information about the ports that
must be opened for Active Directory to function correctly through a firewall.
Firewall Rules for View Client with Local Mode
View Client with Local Mode data is downloaded and uploaded through port 902. If you intend to use View
Client with Local Mode, port 902 must be accessible to your ESX host.
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Overview of Steps to Setting Up a
VMware View Environment
6
Complete these high-level tasks to install VMware View and configure an initial deployment.
Table 6-1. View Installation and Setup Check List
Step
Task
1
Set up the required administrator users and groups in Active Directory.
Instructions: VMware View Installation and vSphere documentation
2
If you have not yet done so, install and set up VMware ESX/ESXi hosts and vCenter Server.
Instructions: vSphere documentation
3
If you are going to deploy linked-clone desktops, install View Composer on the vCenter Server system.
Instructions: VMware View Installation document
4
Install and set up View Connection Server.
Instructions: VMware View Installation document
5
If you are going to use desktops in local mode, install Transfer Server.
Instructions: VMware View Installation document
6
Create one or more virtual machines that can be used as a template for full-clone desktop pools or as a parent
for linked-clone desktop pools.
Instructions: VMware View Administration document
7
Create a desktop pool.
Instructions: VMware View Administration document
8
Control user access to desktops.
Instructions: VMware View Administration document
9
Install View Client on end users' machines and have end users access their View desktops.
Instructions: VMware View Installation
10
(Optional) Create and configure additional administrators to allow different levels of access to specific
inventory objects and settings.
Instructions: VMware View Administration document
11
(Optional) Configure policies to control the behavior of View components, desktop pools, and desktop users.
Instructions: VMware View Administration document
12
(Optional) For added security, integrate smart card authentication and RSA SecurID solutions.
Instructions: VMware View Administration document
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Index
Symbols
.vmdk files 33
A
Active Directory 9, 27, 53
ADM template files 56
Administration Server 64
administrator roles 56
Adobe Flash 23
agent, View 12
AJP13 protocol 60, 61
application virtualization and provisioning 25–27
architectural design elements 29
B
back-end firewall
configuring 59
rules 60
bandwidth 44, 45
base image for virtual desktops 24, 25
browsers, supported 11
Business Intelligence software 13
C
check list for setting up VMware View 67
client connections
direct 51
PCoIP Secure Gateway 50, 57, 64
tunnel 51
client systems, best practices for securing 56
clones, linked 12, 26
cluster, vSphere 42
communication protocols, understanding 61
connection types
client 49
direct 51
external client 57
PCoIP Secure Gateway 50, 57, 64
tunnel 51
cores, virtual machines density 33
CPU estimates 33, 38
credentials, user 54
database types 43
datastores 25
dedicated-assignment desktop pools 23, 25
delegated administration 56
demilitarized zone 57–59, 64
desktop 11
desktop as a managed service (DaaS) 7
desktop pools 12, 23, 25, 35
desktop sources 23
diagram of a View deployment 9
direct client connections 40, 51
disk space allocation for virtual desktops 33, 38
display protocols
defined 17
HP RGS 15, 18, 51
Microsoft RDP 15, 18, 51
PCoIP 51, 57
View PCoIP 9, 15, 17
Distributed Resource Scheduler (DRS) 42
DMZ 10, 57–59, 64
dual-firewall topology 59
E
encryption
of user credentials 54
supported by Microsoft RDP 18
supported with PCoIP 17
entitlements, restricted 55
ESX hosts 34
F
feature support matrix 15
Fibre Channel SAN arrays 24
firewall rules
Active Directory 66
View Agent 65
View Client with Local Mode 66
View Connection Server 65
firewalls
back-end 59
front-end 59
rules 60
floating-assignment desktop pools 23
D
database sizing 40
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front-end firewall
configuring 59
rules 60
N
G
O
gateway server 64
GPOs, security settings for View desktops 56
H
HA cluster 40, 42
HP RGS 15, 18, 51
I
I/O storms 44
iSCSI SAN arrays 24
J
Java Message Service 65
Java Message Service protocol 60
JMS protocol 60, 61
K
kiosk mode 38
knowledge workers 30, 31, 36
L
latency 45
LDAP configuration data 13
LDAP directory 10, 65
legacy PCs 10
linked clones 12, 25, 26, 40, 44
Linux clients 11
load balancing, View Connection Server 46, 58
local desktop use, benefits 18
local desktops, View Transfer Server 13
local mode, See local desktop
local mode users 37
Log in as current user feature 21, 54
LUNs 25
M
Mac clients 10, 11
media file formats supported 21
memory allocation for virtual machines 31, 38
messaging router 65
Microsoft RDP 15, 18, 21, 51
Microsoft Remote Desktop Connection Client for
Mac 11
multimedia redirection (MMR) 21
multimedia streaming 21
multiple monitors 9, 17, 18, 21
70
NAS arrays 24
network bandwidth 44, 45
Offline Desktop (Local Mode), See local desktop
P
parent virtual machine 25, 26
PCoIP 7, 9, 15, 17, 51, 57, 64
PCoIP Secure Gateway connection 50, 57, 64
persistent disks 25
physical PCs 40
policies, desktop 27
pools
desktop 25, 35
kiosk users 38
knowledge workers 36
local mode users 37
task workers 36
pools, desktop 12, 23
power users 30
printers 15
printing, virtual 20
processing requirements 33
professional services 5
provisioning desktops 7
R
RAM allocation for virtual machines 31, 38
rebalance feature 25
recompose feature 26
refresh feature 26, 33
remote desktops, compared to local
desktops 18
replicas 25
restricted entitlements 55
RSA key size, changing 65
RSA SecurID authentication 53
S
scalability, planning for 29
SCOM 13
SCSI adapter types 38
security features, planning 49
security servers
best practices for deploying 57
firewall rules for 60
implementing 57
load balancing 58
overview 10
PCoIP Secure Gateway 64
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Index
setup, VMware View 67
shared storage 24, 44
single sign-on (SSO) 12, 21, 54
smart card authentication 53
smart card readers 20, 53
snapshots 26
software provisioning 26, 27
storage, reducing, with View Composer 24, 25
storage bandwidth 44
storage configurations 44
streaming applications 26
streaming multimedia 21
suspend files 31, 33
swap files 31
T
task workers 30, 31, 36
TCP ports
Active Directory 66
View Agent 65
View Client with Local Mode 66
View Connection Server 65
technical support 5
templates, GPO 27
terminal servers 40
thin client support 10, 15
ThinApp 26
tunnel connection 40, 51
tunneled communications 52, 64
U
UDP ports 60
Unified Access 40
USB devices, using with View desktops 9, 15,
20
USB redirection 20
user authentication
Active Directory 53
methods 52
RSA SecurID 53
smart cards 53
user types 30
View Client for Linux 11
View Client with Local Mode, connections 52
View Composer, operations 40, 44
View Connection Server
configuration 12, 27, 40
grouping 58
load balancing 58
overview 10
RSA SecurID authentication 53
smart card authentication 53
View deployment diagram 9
View desktop configurations 29
View Messaging 65
View node configuration 34
View Open Client 11
View pod 46
View Portal 10, 11
View PowerCLI 13
View Secure Gateway Server 64
View Transfer Server
configuration 41
synchronizing local desktops 13
virtual machine configuration
for vCenter 40
for View Composer 40
for View Connection Server 40
for View desktops 29
for View Transfer Server 41
virtual printing feature 9, 15, 20
virtual private networks 17, 57
VMotion 42
VMware View with Local Mode, See local
desktop
vSphere 7, 9, 24
vSphere cluster 42, 43
W
WAN configurations 43
WAN support 45
Windows page file 33
worker types 29–31, 33, 35
Wyse MMR 15, 21
V
vCenter, configuration 40
vCenter Server 12, 23
vdmadmin command 13
View Administrator 12, 27
View Agent 12, 27
View Broker 64
View building block 43, 44
View Client 11, 27
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