Provisioning a virtual machine (VM) in Azure requires some additional components besides the VM itself, including networking and storage resources. This article shows best practices for running a Windows VM on Azure.
Download a Visio file of this architecture.
A resource group is a logical container that holds related Azure resources. In general, group resources based on their lifetime and who will manage them.
Put closely associated resources that share the same lifecycle into the same resource group. Resource groups allow you to deploy and monitor resources as a group and track billing costs by resource group. You can also delete resources as a set, which is very useful for test deployments. Assign meaningful resource names to simplify locating a specific resource and understanding its role. For more information, see Recommended Naming Conventions for Azure Resources.
You can provision a VM from a list of published images, or from a custom managed image or virtual hard disk (VHD) file uploaded to Azure Blob storage.
Azure offers many different virtual machine sizes. For more information, see Sizes for virtual machines in Azure. If you are moving an existing workload to Azure, start with the VM size that's the closest match to your on-premises servers. Then measure the performance of your actual workload in terms of CPU, memory, and disk input/output operations per second (IOPS), and adjust the size as needed.
Generally, choose an Azure region that is closest to your internal users or customers. Not all VM sizes are available in all regions. For more information, see Services by region. For a list of the VM sizes available in a specific region, run the following command from the Azure CLI:
az vm list-sizes --location <location>
For information about choosing a published VM image, see Find Windows VM images.
For best disk I/O performance, we recommend Premium Storage, which stores data on solid-state drives (SSDs). Cost is based on the capacity of the provisioned disk. IOPS and throughput also depend on disk size, so when you provision a disk, consider all three factors (capacity, IOPS, and throughput).
We also recommend using Managed Disks. Managed disks simplify disk management by handling the storage for you. Managed disks do not require a storage account. You simply specify the size and type of disk and it is deployed as a highly available resource
The OS disk is a VHD stored in Azure Storage, so it persists even when the host machine is down. We also recommend creating one or more data disks, which are persistent VHDs used for application data. When possible, install applications on a data disk, not the OS disk. Some legacy applications might need to install components on the C: drive; in that case, you can resize the OS disk using PowerShell.
The VM is also created with a temporary disk (the
D: drive on Windows). This disk is stored on a physical drive on the host machine. It is not saved in Azure Storage and may be deleted during reboots and other VM lifecycle events. Use this disk only for temporary data, such as page or swap files.
The networking components include the following resources:
Virtual network. Every VM is deployed into a virtual network that can be segmented into multiple subnets.
Network interface (NIC). The NIC enables the VM to communicate with the virtual network. If you need multiple NICs for your VM, be aware that a maximum number of NICs is defined for each VM size.
Public IP address. A public IP address is needed to communicate with the VM — for example, via remote desktop (RDP). The public IP address can be dynamic or static. The default is dynamic.
Reserve a static IP address if you need a fixed IP address that won't change — for example, if you need to create a DNS 'A' record or add the IP address to a safe list.
You can also create a fully qualified domain name (FQDN) for the IP address. You can then register a CNAME record in DNS that points to the FQDN. For more information, see Create a fully qualified domain name in the Azure portal.
Network security group (NSG). Network security groups are used to allow or deny network traffic to VMs. NSGs can be associated either with subnets or with individual VM instances.
All NSGs contain a set of default rules, including a rule that blocks all inbound Internet traffic. The default rules cannot be deleted, but other rules can override them. To enable Internet traffic, create rules that allow inbound traffic to specific ports — for example, port 80 for HTTP. To enable RDP, add an NSG rule that allows inbound traffic to TCP port 3389.
Diagnostics. Enable monitoring and diagnostics, including basic health metrics, diagnostics infrastructure logs, and boot diagnostics. Boot diagnostics can help you diagnose boot failure if your VM gets into a non-bootable state. Create an Azure Storage account to store the logs. A standard locally redundant storage (LRS) account is sufficient for diagnostic logs. For more information, see Enable monitoring and diagnostics.
Availability. Your VM may be affected by planned maintenance or unplanned downtime. You can use VM reboot logs to determine whether a VM reboot was caused by planned maintenance. For higher availability, deploy multiple VMs in an availability set. This configuration provides a higher service level agreement (SLA).
Backups To protect against accidental data loss, use the Azure Backup service to back up your VMs to geo-redundant storage. Azure Backup provides application-consistent backups.
Stopping a VM. Azure makes a distinction between "stopped" and "deallocated" states. You are charged when the VM status is stopped, but not when the VM is deallocated. In the Azure portal, the Stop button deallocates the VM. If you shut down through the OS while logged in, the VM is stopped but not deallocated, so you will still be charged.
Deleting a VM. If you delete a VM, the VHDs are not deleted. That means you can safely delete the VM without losing data. However, you will still be charged for storage. To delete the VHD, delete the file from Blob storage. To prevent accidental deletion, use a resource lock to lock the entire resource group or lock individual resources, such as a VM.
These considerations implement the pillars of the Azure Well-Architected Framework, which is a set of guiding tenets that can be used to improve the quality of a workload. For more information, see Microsoft Azure Well-Architected Framework.
Cost optimization is about looking at ways to reduce unnecessary expenses and improve operational efficiencies. For more information, see Overview of the cost optimization pillar.
There are various options for VM sizes depending on the usage and workload. The range includes most economical option of the Bs-series to the newest GPU VMs optimized for machine learning. For information about the available options, see Azure Windows VM pricing.
For workloads with no predictable time of completion or resource consumption, consider the Pay as you go option.
Consider using Azure Reservations if you can commit to using a virtual machine over a one-year or three-year term. VM reservations can reduce costs up to 72 % compared to pay-as-you-go prices.
Use Azure Spot VMs to run workloads the can be interrupted and do not require completion within a predetermined timeframe or an SLA. Azure deploys Spot VMs if there is available capacity and evicts when it needs the capacity back. Costs associated with Spot virtual machines are significantly lower. Consider Spot VMs for these workloads:
- High-performance computing scenarios, batch processing jobs, or visual rendering applications.
- Test environments, including continuous integration and continuous delivery workloads.
- Large-scale stateless applications.
Use the [Azure Pricing Calculator][azure-pricing-calculator] to estimates costs.
For more information, see the cost section in Microsoft Azure Well-Architected Framework.
Security provides assurances against deliberate attacks and the abuse of your valuable data and systems. For more information, see Overview of the security pillar.
Use Microsoft Defender for Cloud to get a central view of the security state of your Azure resources. Defender for Cloud monitors potential security issues and provides a comprehensive picture of the security health of your deployment. Defender for Cloud is configured per Azure subscription. Enable security data collection as described in Onboard your Azure subscription to Defender for Cloud Standard. When data collection is enabled, Defender for Cloud automatically scans any VMs created under that subscription.
Patch management. If enabled, Defender for Cloud checks whether any security and critical updates are missing. Use Group Policy settings on the VM to enable automatic system updates.
Antimalware. If enabled, Defender for Cloud checks whether antimalware software is installed. You can also use Defender for Cloud to install antimalware software from inside the Azure portal.
Access control. Use Azure role-based access control (Azure RBAC) to control access to Azure resources. Azure RBAC lets you assign authorization roles to members of your DevOps team. For example, the Reader role can view Azure resources but not create, manage, or delete them. Some permissions are specific to an Azure resource type. For example, the Virtual Machine Contributor role can restart or deallocate a VM, reset the administrator password, create a new VM, and so on. Other built-in roles that may be useful for this architecture include DevTest Labs User and Network Contributor.
Azure RBAC does not limit the actions that a user logged into a VM can perform. Those permissions are determined by the account type on the guest OS.
Audit logs. Use audit logs to see provisioning actions and other VM events.
Data encryption. Use Azure Disk Encryption if you need to encrypt the OS and data disks.
Operational excellence covers the operations processes that deploy an application and keep it running in production. For more information, see Overview of the operational excellence pillar.
Use infrastructure as Code (IaC) either by using a single Azure Resource Manager template for provisioning the Azure resources (declarative approach) or by using a single PowerShell script (imperative approach). Since all the resources are in the same virtual network, they are isolated in the same basic workload, that makes it easier to associate the workload's specific resources to a DevOps team, so that the team can independently manage all aspects of those resources. This isolation enables the DevOps Team and Services to perform continuous integration and continuous delivery (CI/CD).
Also, you can use different Azure Resource Manager templates and integrate them with Azure DevOps Services to provision different environments in minutes, for example to replicate production like scenarios or load testing environments only when needed, saving cost.
For higher availability architecture see Windows N-tier application on Azure with SQL Server, the reference architecture includes more than one VM and each VM is included in an availability set.
Consider using the Azure Monitor to Analyze and optimize the performance of your infrastructure, Monitor and diagnose networking issues without logging into your virtual machines.
- To create a Windows VM, see Quickstart: Create a Windows virtual machine in the Azure portal
- To install NVIDIA drivers on a Windows VM, see Install NVIDIA GPU drivers on N-series VMs running Windows
- To install AMD drivers on a Windows VM, see Install AMD GPU drivers on N-series VMs running Windows
- To provision a Windows VM, see Create and Manage Windows VMs with Azure PowerShell