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Plan volumes on Azure Stack HCI and Windows Server clusters

Applies to: Azure Stack HCI, versions 22H2 and 21H2; Windows Server 2022, Windows Server 2019

This article provides guidance for how to plan cluster volumes to meet the performance and capacity needs of your workloads, including choosing their filesystem, resiliency type, and size.

Note

Storage Spaces Direct does not support a file server for general use. If you need to run the file server or other generic services on Storage Space Direct, configure it on the virtual machines.

Review: What are volumes

Volumes are where you put the files your workloads need, such as VHD or VHDX files for Hyper-V virtual machines. Volumes combine the drives in the storage pool to introduce the fault tolerance, scalability, and performance benefits of Storage Spaces Direct, the software-defined storage technology behind Azure Stack HCI and Windows Server.

Note

We use term "volume" to refer jointly to the volume and the virtual disk under it, including functionality provided by other built-in Windows features such as Cluster Shared Volumes (CSV) and ReFS. Understanding these implementation-level distinctions is not necessary to plan and deploy Storage Spaces Direct successfully.

Diagram shows three folders labeled as volumes each associated with a virtual disk labeled as volumes, all associated with a common storage pool of disks.

All volumes are accessible by all servers in the cluster at the same time. Once created, they show up at C:\ClusterStorage\ on all servers.

Screen capture shows a file explorer window titled ClusterStorage that contains volumes named Volume1, Volume2, and Volume3.

Choosing how many volumes to create

We recommend making the number of volumes a multiple of the number of servers in your cluster. For example, if you have 4 servers, you'll experience more consistent performance with 4 total volumes than with 3 or 5. This allows the cluster to distribute volume "ownership" (one server handles metadata orchestration for each volume) evenly among servers.

We recommend limiting the total number of volumes to 64 volumes per cluster.

Choosing the filesystem

We recommend using the new Resilient File System (ReFS) for Storage Spaces Direct. ReFS is the premier filesystem purpose-built for virtualization and offers many advantages, including dramatic performance accelerations and built-in protection against data corruption. It supports nearly all key NTFS features, including Data Deduplication in Windows Server version 1709 and later. See the ReFS feature comparison table for details.

If your workload requires a feature that ReFS doesn't support yet, you can use NTFS instead.

Tip

Volumes with different file systems can coexist in the same cluster.

Choosing the resiliency type

Volumes in Storage Spaces Direct provide resiliency to protect against hardware problems, such as drive or server failures, and to enable continuous availability throughout server maintenance, such as software updates.

Note

Which resiliency types you can choose is independent of which types of drives you have.

With two servers

With two servers in the cluster, you can use two-way mirroring or you can use nested resiliency.

Two-way mirroring keeps two copies of all data, one copy on the drives in each server. Its storage efficiency is 50 percent; to write 1 TB of data, you need at least 2 TB of physical storage capacity in the storage pool. Two-way mirroring can safely tolerate one hardware failure at a time (one server or drive).

Diagram shows volumes labeled data and copy connected by circular arrows and both volumes are associated with a bank of disks in servers.

Nested resiliency provides data resiliency between servers with two-way mirroring, then adds resiliency within a server with two-way mirroring or mirror-accelerated parity. Nesting provides data resilience even when one server is restarting or unavailable. Its storage efficiency is 25 percent with nested two-way mirroring and around 35-40 percent for nested mirror-accelerated parity. Nested resiliency can safely tolerate two hardware failures at a time (two drives, or a server and a drive on the remaining server). Because of this added data resilience, we recommend using nested resiliency on production deployments of two-server clusters. For more info, see Nested resiliency.

Diagram shows nested mirror accelerated parity with two-way mirror between servers associated with a two-way mirror within each server corresponding to a parity layer within each server.

With three servers

With three servers, you should use three-way mirroring for better fault tolerance and performance. Three-way mirroring keeps three copies of all data, one copy on the drives in each server. Its storage efficiency is 33.3 percent – to write 1 TB of data, you need at least 3 TB of physical storage capacity in the storage pool. Three-way mirroring can safely tolerate at least two hardware problems (drive or server) at a time. If 2 nodes become unavailable the storage pool loses quorum, since 2/3 of the disks aren't available, and the virtual disks are unaccessible. However, a node can be down and one or more disks on another node can fail and the virtual disks remain online. For example, if you're rebooting one server when suddenly another drive or server fails, all data remains safe and continuously accessible.

Diagram shows a volume labeled data and two labeled copy connected by circular arrows with each volume associated with a server containing physical disks.

With four or more servers

With four or more servers, you can choose for each volume whether to use three-way mirroring, dual parity (often called "erasure coding"), or mix the two with mirror-accelerated parity.

Dual parity provides the same fault tolerance as three-way mirroring but with better storage efficiency. With four servers, its storage efficiency is 50.0 percent; to store 2 TB of data, you need 4 TB of physical storage capacity in the storage pool. This increases to 66.7 percent storage efficiency with seven servers, and continues up to 80.0 percent storage efficiency. The tradeoff is that parity encoding is more compute-intensive, which can limit its performance.

Diagram shows two volumes labeled data and two labeled parity connected by circular arrows with each volume associated with a server containing physical disks.

Which resiliency type to use depends on the performance and capacity requirements for your environment. Here's a table that summarizes the performance and storage efficiency of each resiliency type.

Resiliency type Capacity efficiency Speed
Mirror Storage efficiency showing 33%
Three-way mirror: 33%
Two-way-mirror: 50%
Performance showing 100%
Highest performance
Mirror-accelerated parity Storage efficiency showing around 50%
Depends on proportion of mirror and parity
Performance showing around 20%
Much slower than mirror, but up to twice as fast as dual-parity
Best for large sequential writes and reads
Dual-parity Storage efficiency showing around 80%
4 servers: 50%
16 servers: up to 80%
Performance showing around 10%
Highest I/O latency & CPU usage on writes
Best for large sequential writes and reads

When performance matters most

Workloads that have strict latency requirements or that need lots of mixed random IOPS, such as SQL Server databases or performance-sensitive Hyper-V virtual machines, should run on volumes that use mirroring to maximize performance.

Tip

Mirroring is faster than any other resiliency type. We use mirroring for nearly all our performance examples.

When capacity matters most

Workloads that write infrequently, such as data warehouses or "cold" storage, should run on volumes that use dual parity to maximize storage efficiency. Certain other workloads, such as Scale-Out File Server (SoFS), virtual desktop infrastructure (VDI), or others that don't create lots of fast-drifting random IO traffic and/or don't require the best performance may also use dual parity, at your discretion. Parity inevitably increases CPU utilization and IO latency, particularly on writes, compared to mirroring.

When data is written in bulk

Workloads that write in large, sequential passes, such as archival or backup targets, have another option: one volume can mix mirroring and dual parity. Writes land first in the mirrored portion and are gradually moved into the parity portion later. This accelerates ingestion and reduces resource utilization when large writes arrive by allowing the compute-intensive parity encoding to happen over a longer time. When sizing the portions, consider that the quantity of writes that happen at once (such as one daily backup) should comfortably fit in the mirror portion. For example, if you ingest 100 GB once daily, consider using mirroring for 150 GB to 200 GB, and dual parity for the rest.

The resulting storage efficiency depends on the proportions you choose.

Tip

If you observe an abrupt decrease in write performance partway through data ingestion, it may indicate that the mirror portion is not large enough or that mirror-accelerated parity isn't well suited for your use case. As an example, if write performance decreases from 400 MB/s to 40 MB/s, consider expanding the mirror portion or switching to three-way mirror.

About deployments with NVMe, SSD, and HDD

In deployments with two types of drives, the faster drives provide caching while the slower drives provide capacity. This happens automatically – for more information, see Understanding the cache in Storage Spaces Direct. In such deployments, all volumes ultimately reside on the same type of drives – the capacity drives.

In deployments with all three types of drives, only the fastest drives (NVMe) provide caching, leaving two types of drives (SSD and HDD) to provide capacity. For each volume, you can choose whether it resides entirely on the SSD tier, entirely on the HDD tier, or whether it spans the two.

Important

We recommend using the SSD tier to place your most performance-sensitive workloads on all-flash.

Choosing the size of volumes

We recommend limiting the size of each volume to 64 TB in Azure Stack HCI.

Tip

If you use a backup solution that relies on the Volume Shadow Copy service (VSS) and the Volsnap software provider—as is common with file server workloads—limiting the volume size to 10 TB will improve performance and reliability. Backup solutions that use the newer Hyper-V RCT API and/or ReFS block cloning and/or the native SQL backup APIs perform well up to 32 TB and beyond.

Footprint

The size of a volume refers to its usable capacity, the amount of data it can store. This is provided by the -Size parameter of the New-Volume cmdlet and then appears in the Size property when you run the Get-Volume cmdlet.

Size is distinct from volume's footprint, the total physical storage capacity it occupies on the storage pool. The footprint depends on its resiliency type. For example, volumes that use three-way mirroring have a footprint three times their size.

The footprints of your volumes need to fit in the storage pool.

Diagram shows a 2 TB volume compared to a 6 TB footprint in the storage pool with a multiplier of three specified.

Reserve capacity

Leaving some capacity in the storage pool unallocated gives volumes space to repair "in-place" after drives fail, improving data safety and performance. If there's sufficient capacity, an immediate, in-place, parallel repair can restore volumes to full resiliency even before the failed drives are replaced. This happens automatically.

We recommend reserving the equivalent of one capacity drive per server, up to 4 drives. You may reserve more at your discretion, but this minimum recommendation guarantees an immediate, in-place, parallel repair can succeed after the failure of any drive.

Diagram shows a volume associated with several disks in a storage pool and unassociated disks marked as reserve.

For example, if you have 2 servers and you're using 1 TB capacity drives, set aside 2 x 1 = 2 TB of the pool as reserve. If you have 3 servers and 1 TB capacity drives, set aside 3 x 1 = 3 TB as reserve. If you have 4 or more servers and 1 TB capacity drives, set aside 4 x 1 = 4 TB as reserve.

Note

In clusters with drives of all three types (NVMe + SSD + HDD), we recommend reserving the equivalent of one SSD plus one HDD per server, up to 4 drives of each.

Example: Capacity planning

Consider one four-server cluster. Each server has some cache drives plus sixteen 2 TB drives for capacity.

4 servers x 16 drives each x 2 TB each = 128 TB

From this 128 TB in the storage pool, we set aside four drives, or 8 TB, so that in-place repairs can happen without any rush to replace drives after they fail. This leaves 120 TB of physical storage capacity in the pool with which we can create volumes.

128 TB – (4 x 2 TB) = 120 TB

Suppose we need our deployment to host some highly active Hyper-V virtual machines, but we also have lots of cold storage – old files and backups we need to retain. Because we have four servers, let's create four volumes.

Let's put the virtual machines on the first two volumes, Volume1 and Volume2. We choose ReFS as the filesystem (for the faster creation and checkpoints) and three-way mirroring for resiliency to maximize performance. Let's put the cold storage on the other two volumes, Volume 3 and Volume 4. We choose NTFS as the filesystem (for Data Deduplication) and dual parity for resiliency to maximize capacity.

We aren't required to make all volumes the same size, but for simplicity, let's – for example, we can make them all 12 TB.

Volume1 and Volume2 each occupy 12 TB x 33.3 percent efficiency = 36 TB of physical storage capacity.

Volume3 and Volume4 each occupy 12 TB x 50.0 percent efficiency = 24 TB of physical storage capacity.

36 TB + 36 TB + 24 TB + 24 TB = 120 TB

The four volumes fit exactly on the physical storage capacity available in our pool. Perfect!

Diagram shows two 12 TB three-way mirror volumes each associated with 36 TB of storage and two 12 TB dual parity volumes each associated with 24 TB, all taking up 120 TB in a storage pool.

Tip

You don't need to create all the volumes right away. You can always extend volumes or create new volumes later.

For simplicity, this example uses decimal (base-10) units throughout, meaning 1 TB = 1,000,000,000,000 bytes. However, storage quantities in Windows appear in binary (base-2) units. For example, each 2 TB drive would appear as 1.82 TiB in Windows. Likewise, the 128 TB storage pool would appear as 116.41 TiB. This is expected.

Usage

See Creating volumes in Azure Stack HCI.

Next steps

For more information, see also: