Create a Linux virtual Machine in Azure
We have an existing website running on a local Ubuntu Linux server. Our goal is to create an Azure virtual machine (VM) using the latest Ubuntu image and then migrate the site to the cloud. In this unit, you'll learn about the options you'll need to evaluate when creating a virtual machine in Azure.
Introduction to Azure Virtual Machines
Azure Virtual Machines are an on-demand, scalable cloud-computing resource. They include processors, memory, storage, and networking resources. You can start and stop virtual machines at will and manage them from the Azure portal or with the Azure CLI. You can also use a remote Secure Shell (SSH) to connect directly to the running VM and execute commands as if you were on a local computer.
Run Linux in Azure
Creating Linux-based VMs in Azure is easy. Microsoft has partnered with prominent Linux vendors to ensure their distributions are optimized for the Azure platform. You can create virtual machines from prebuilt images for a variety of popular Linux distributions, such as SUSE, Red Hat, and Ubuntu, or build your own Linux distribution to run in the cloud.
Create an Azure VM
VMs can be defined and deployed on Azure in several ways: the Azure portal, a script (using the Azure CLI or Azure PowerShell), or an Azure Resource Manager template. In all cases, you'll need to supply several pieces of information that we'll cover shortly.
The Azure Marketplace also provides preconfigured images that include both an OS and favorite software tools installed for specific scenarios.
Resources used in a Linux VM
When creating a Linux VM in Azure, you also create resources to host the VM. These resources work together to virtualize a computer and run the Linux operating system. These resources must exist (and be selected during VM creation), or they'll be created with the VM:
- A virtual machine that provides CPU and memory resources
- An Azure Storage account to hold the virtual hard disks
- Virtual disks to hold the OS, applications, and data
- A virtual network (VNet) to connect the VM to other Azure services or your on-premises hardware
- A network interface to communicate with the VNet
- An optional public IP address so you can access the VM
Like other Azure services, you'll need a Resource Group to contain the VM (and optionally group these resources for administration). When you create a new VM, you can either use an existing resource group or create a new one.
Choose the VM image
Selecting an image is one of the first and most important decisions you'll make when creating a VM. An image is a template that's used to create a VM. These templates include an OS and often other software, such as development tools or web-hosting environments.
Anything that a computer can have installed can be included in an image. You can create a VM from an image that's preconfigured to precisely the tasks you need, such as hosting a web app on the Apache HTTP Server.
You can also create and upload custom disk images.
Size your VM
Just as a physical machine has a certain amount of memory and CPU power, so too does a virtual machine. Azure offers a range of VMs of differing sizes at different price points. The size that you choose will determine the VM's processing power, memory, and maximum storage capacity.
There are quota limits on each subscription that can impact VM creation. If you run into these quota limits you can open an online customer support request to increase your limits.
VM sizes are grouped into categories, starting with the B-series for basic testing and running up to the H-series for massive computing tasks. You should select the size of the VM based on the workload you want to perform. It's possible to change the size of a VM after it's been created, but the VM must be stopped first, so it's best to size it appropriately from the start if possible.
Here are some guidelines based on the scenario you are targeting
|What are you doing?||Consider these sizes|
|General use computing/web: Testing and development, small to medium databases, or low to medium traffic web servers.||B, Dsv3, Dv3, DSv2, Dv2|
|Heavy computational tasks: Medium traffic web servers, network appliances, batch processes, and application servers.||Fsv2, Fs, F|
|Large memory usage: Relational database servers, medium to large caches, and in-memory analytics.||Esv3, Ev3, M, GS, G, DSv2, Dv2|
|Data storage and processing: Big data, SQL, and NoSQL databases that need high disk throughput and I/O.||Ls|
|Heavy graphics rendering or video editing, as well as model training and inferencing (ND) with deep learning.||NV, NC, NCv2, NCv3, ND|
|High-performance computing (HPC): Your workloads need the fastest and most powerful CPU virtual machines with optional high-throughput network interfaces.||H|
Choose storage options
The next set of decisions revolves around storage. First, you can choose the disk technology. Options include a traditional platter-based hard disk drive (HDD) or a more modern solid-state drive (SSD). Just like the hardware you purchase, SSD storage costs more but provides better performance.
There are two levels of SSD storage available: standard and premium. Choose Standard SSD disks if you have normal workloads but want better performance. Choose Premium SSD disks if you have I/O intensive workloads or mission-critical systems that need to process data very quickly.
Map storage to disks
Azure uses virtual hard disks (VHDs) to represent physical disks for the VM. VHDs replicate the logical format and data of a disk drive but are stored as page blobs in an Azure Storage account. You can choose on a per disk basis what type of storage it should use (SSD or HDD). This allows you to control the performance of each disk, likely based on the I/O you plan to perform on it.
By default, two virtual hard disks (VHDs) will be created for your Linux VM:
The operating system disk: This is your primary drive, and it has a maximum capacity of 2048 GB. It will be labeled as
A temporary disk: This provides temporary storage for the OS or any apps. On Linux virtual machines, the disk is
/dev/sdband is formatted and mounted to
/mntby the Azure Linux Agent. It's sized based on the VM size, and is used to store the swap file.
The temporary disk is not persistent. You should only write data to this disk that is not critical to the system.
What about data?
You can store data on the primary drive along with the OS, but a better approach is to create dedicated data disks. You can create and attach additional disks to the VM. Each disk can hold up to 32,767 gibibytes (GiB) of data, with the maximum amount of storage determined by the VM size you select.
Azure virtual disk sizes are measured in Gibibytes (GiB), which are not the same as Gigabytes (GB); one GiB is approximately 1.074 GB. Therefore, to obtain an approximate equivalent of your virtual disk size in GB, multiply the size in GiB by 1.074, and that will return a size in GB that is relatively close. For example, 32,767 GiB would be approximately 35,183 GB.
An interesting capability is to create a VHD image from a real disk. This allows you to easily migrate existing information from an on-premises computer to the cloud.
Unmanaged vs. managed disks
The final storage choice you'll make is whether to use unmanaged or managed disks.
With unmanaged disks, you're responsible for the storage accounts that are used to hold the VHDs that correspond to your VM disks. You pay the storage account rates for the amount of space you use. A single storage account has a fixed rate limit of 20,000 I/O operations/sec. This means that a single storage account is capable of supporting 40 standard virtual hard disks at full throttle. If you need to scale out, then you need more than one storage account, which can get complicated.
Managed disks are the newer and recommended disk storage model. They elegantly solve this complexity by putting the burden of managing the storage accounts onto Azure. You'll specify the disk type (Premium or Standard) and the size of the disk, and Azure creates and manages both the disk and the storage it uses. You don't have to worry about storage account limits, which makes them easier to scale out. They also offer several other benefits:
- Increased reliability: Azure ensures that VHDs associated with high-reliability VMs will be placed in different parts of Azure Storage to provide similar levels of resilience.
- Better security: Managed disks are real, managed resources in the resource group. This means they can use role-based access control to restrict who can work with the VHD data.
- Snapshot support: You can use snapshots to create a read-only copy of a VHD. We recommend that you shut down the VM to clear out any processes that are in progress. Creating the snapshot only takes a few seconds. Once it's done, you can power on the VM and use the snapshot to create a duplicate VM to troubleshoot a production issue or roll back the VM to the point in time that you took the snapshot.
- Backup support: Managed disks can be automatically backed up to different regions for disaster recovery with Azure Backup without affecting the VM's service.
Virtual machines communicate with external resources using a virtual network (VNet). The VNet represents a private network in a single region on which your resources communicate. A virtual network is just like the networks you manage on-premises. You can divide them up with subnets to isolate resources, connect them to other networks (including your on-premises networks), and apply traffic rules to govern inbound and outbound connections.
Plan your network
When you create a new VM, you'll have the option of creating a new virtual network or using an existing VNet in your region.
Having Azure create the network together with the VM is simple, but it's likely not ideal for most scenarios. It's better to plan your network requirements up front for all the components in your architecture and create the VNet structure separately. Then, create the VMs and place them into the already-created VNets. We'll look more at virtual networks later in this module.
Before we create a virtual machine, we need to decide how we'd like to administer the VM. Let's look at our options.
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