Muokkaa

Jaa


Use RoboCopy to migrate to Azure file shares

This migration article describes the use of RoboCopy to move or migrate files to an SMB Azure file share. RoboCopy is a trusted and well-known file copy utility with a feature set that makes it well suited for migrations. It uses the SMB protocol, which makes it broadly applicable to any source and target combination that supports SMB.

  • Data sources: Any source supporting the SMB protocol, such as Network Attached Storage (NAS), Windows or Linux servers, another Azure file share, and many more
  • Migration route: From source storage ⇒ Windows machine with RoboCopy ⇒ Azure file share
  • No caching files on-premises: Because the final goal is to use the Azure file shares directly in the cloud, there's no plan to use Azure File Sync.

There are many different migration routes for different source and deployment combinations. See the table of migration guides to find the migration that best suits your needs.

Applies to

File share type SMB NFS
Standard file shares (GPv2), LRS/ZRS Yes No
Standard file shares (GPv2), GRS/GZRS Yes No
Premium file shares (FileStorage), LRS/ZRS Yes No

AzCopy vs. RoboCopy

AzCopy and RoboCopy are two fundamentally different file copy tools. RoboCopy uses any version of the SMB protocol. AzCopy is a "born-in-the-cloud" tool that can be used to move data as long as the target is in Azure storage. AzCopy depends on a REST protocol.

RoboCopy, as a trusted, Windows-based copy tool, has the home-turf advantage when it comes to copying files at full fidelity. RoboCopy supports many migration scenarios due to its rich set of features and the ability to copy files and folders in full fidelity. Check out the file fidelity section in the migration overview article to learn more about the importance of copying files at maximum possible fidelity.

AzCopy, on the other hand, has only recently expanded to support file copy with some fidelity and added the first features needed to be considered as a migration tool. However, there are still gaps, and there can easily be misunderstandings of functionality when comparing AzCopy flags to RoboCopy flags.

An example: RoboCopy /MIR will mirror source to target - that means added, changed, and deleted files are considered. An important difference in using AzCopy -sync is that deleted files on the source aren't removed on the target. That makes for an incomplete differential-copy feature set. AzCopy will continue to evolve. At this time, we don't recommend using AzCopy for migration scenarios with Azure file shares as the target.

Migration goals

The goal is to move the data from existing file share locations to Azure. In Azure, you'll store your data in native Azure file shares you can use without a need for a Windows Server. This migration needs to be done in a way that guarantees the integrity of the production data and availability during the migration. The latter requires keeping downtime to a minimum, so that it can fit into or only slightly exceed regular maintenance windows.

Migration overview

The migration process consists of several phases. First, you'll need to deploy Azure storage accounts and file shares. Next, you'll configure networking, consider a DFS Namespace deployment (DFS-N), or update your existing one. Once it's time for the actual data copy, you'll need to consider repeated, differential RoboCopy runs to minimize downtime, and finally, cut-over your users to the newly created Azure file shares. The following sections describe the phases of the migration process in detail.

Phase 1: Deploy Azure storage resources

In this phase, you'll provision the Azure storage accounts and the SMB Azure file shares within them.

Remember that an Azure file share is deployed in the cloud in an Azure storage account. For standard file shares, that arrangement makes the storage account a scale target for performance numbers like IOPS and throughput. If you place multiple file shares in a single storage account, you're creating a shared pool of IOPS and throughput for these shares.

As a general rule, you can pool multiple Azure file shares into the same storage account if you have archival shares or you expect low day-to-day activity in them. However, if you have highly active shares (shares used by many users and/or applications), you'll want to deploy storage accounts with one file share each. These limitations don't apply to FileStorage (premium) storage accounts, where performance is explicitly provisioned and guaranteed for each share.

Note

There's a limit of 250 storage accounts per subscription per Azure region. With a quota increase, you can create up to 500 storage accounts per region. For more information, see Increase Azure Storage account quotas.

Another consideration when you're deploying a storage account is redundancy. See Azure Files redundancy.

If you've made a list of your shares, you should map each share to the storage account it will be created in.

The names of your resources are also important. For example, if you group multiple shares for the HR department into an Azure storage account, you should name the storage account appropriately. Similarly, when you name your Azure file shares, you should use names similar to the ones used for their on-premises counterparts.

Now deploy the appropriate number of Azure storage accounts with the appropriate number of Azure file shares in them, following the instructions in Create an SMB file share. In most cases, you'll want to make sure the region of each of your storage accounts is the same.

Phase 2: Preparing to use Azure file shares

With the information in this phase, you'll be able to decide how your servers and users in Azure and outside of Azure will be enabled to utilize your Azure file shares. The most critical decisions are:

  • Networking: Enable your networks to route SMB traffic.
  • Authentication: Configure Azure storage accounts for Kerberos authentication. Using identity-based authentication and domain joining your storage account will allow your apps and users to use their AD identity to for authentication.
  • Authorization: Share-level ACLs for each Azure file share will allow AD users and groups to access a given share. Within an Azure file share, native NTFS ACLs will take over. Authorization based on file and folder ACLs then works like it does for on-premises SMB shares.
  • Business continuity: Integrating Azure file shares into an existing environment often entails preserving existing share addresses. If you aren't already using DFS-Namespaces, consider establishing that in your environment. You'll be able to keep share addresses your users and scripts use, unchanged. DFS-N provides a namespace routing service for SMB by redirecting clients to Azure file shares.

This video is a guide and demo for how to securely expose Azure file shares directly to information workers and apps in five simple steps.
The video references dedicated documentation for the following topics. Note that Azure Active Directory is now Microsoft Entra ID. For more information, see New name for Azure AD.

Mounting an Azure file share

Before you can use RoboCopy, you need to make the Azure file share accessible over SMB. The easiest way is to mount the share as a local network drive to the Windows Server you're planning on using for RoboCopy.

Important

Make sure you mount the Azure file share using the storage account access key. Don't use a domain identity. Before you can successfully mount an Azure file share to a local Windows Server, you need to have completed Phase 2: Preparing to use Azure file shares.

Once you're ready, review Use an Azure file share with Windows. Then mount the Azure file share you want to start the RoboCopy for.

Phase 3: RoboCopy

The following RoboCopy command will copy only the differences (updated files and folders) from your source storage to your Azure file share.

robocopy <SourcePath> <Dest.Path> /MT:20 /R:2 /W:1 /B /MIR /IT /COPY:DATSO /DCOPY:DAT /NP /NFL /NDL /XD "System Volume Information" /UNILOG:<FilePathAndName> 
Switch Meaning
/MT:n Allows Robocopy to run multithreaded. Default for n is 8. The maximum is 128 threads. While a high thread count helps saturate the available bandwidth, it doesn't mean your migration will always be faster with more threads. Tests with Azure Files indicate between 8 and 20 shows balanced performance for an initial copy run. Subsequent /MIR runs are progressively affected by available compute vs available network bandwidth. For subsequent runs, match your thread count value more closely to your processor core count and thread count per core. Consider whether cores need to be reserved for other tasks that a production server might have. Tests with Azure Files have shown that up to 64 threads produce a good performance, but only if your processors can keep them alive at the same time.
/R:n Maximum retry count for a file that fails to copy on first attempt. Robocopy will try n times before the file permanently fails to copy in the run. You can optimize the performance of your run: Choose a value of two or three if you believe timeout issues caused failures in the past. This may be more common over WAN links. Choose no retry or a value of one if you believe the file failed to copy because it was actively in use. Trying again a few seconds later may not be enough time for the in-use state of the file to change. Users or apps holding the file open may need hours more time. In this case, accepting the file wasn't copied and catching it in one of your planned, subsequent Robocopy runs, may succeed in eventually copying the file successfully. That helps the current run to finish faster without being prolonged by many retries that ultimately end up in a majority of copy failures due to files still open past the retry timeout.
/W:n Specifies the time Robocopy waits before attempting to copy a file that didn't successfully copy during a previous attempt. n is the number of seconds to wait between retries. /W:n is often used together with /R:n.
/B Runs Robocopy in the same mode that a backup application would use. This switch allows Robocopy to move files that the current user doesn't have permissions for. The backup switch depends on running the Robocopy command in an administrator elevated console or PowerShell window. If you use Robocopy for Azure Files, make sure you mount the Azure file share using the storage account access key vs. a domain identity. If you don't, the error messages might not intuitively lead you to a resolution of the problem.
/MIR (Mirror source to target.) Allows Robocopy to copy only deltas between source and target. Empty subdirectories will be copied. Items (files or folders) that have changed or don't exist on the target will be copied. Items that exist on the target but not on the source will be purged (deleted) from the target. When you use this switch, match the source and target folder structures exactly. Matching means copying from the correct source and folder level to the matching folder level on the target. Only then can a "catch up" copy be successful. When source and target are mismatched, using /MIR will lead to large-scale deletions and recopies.
/IT Ensures fidelity is preserved in certain mirror scenarios.
For example, if a file experiences an ACL change and an attribute update between two Robocopy runs, it's marked hidden. Without /IT, the ACL change might be missed by Robocopy and not transferred to the target location.
/COPY:[copyflags] The fidelity of the file copy. Default: /COPY:DAT. Copy flags: D= Data, A= Attributes, T= Timestamps, S= Security = NTFS ACLs, O= Owner information, U= Auditing information. Auditing information can't be stored in an Azure file share.
/DCOPY:[copyflags] Fidelity for the copy of directories. Default: /DCOPY:DA. Copy flags: D= Data, A= Attributes, T= Timestamps.
/NP Specifies that the progress of the copy for each file and folder won't be displayed. Displaying the progress significantly lowers copy performance.
/NFL Specifies that file names aren't logged. Improves copy performance.
/NDL Specifies that directory names aren't logged. Improves copy performance.
/XD Specifies directories to be excluded. When running Robocopy on the root of a volume, consider excluding the hidden System Volume Information folder. If used as designed, all information in there is specific to the exact volume on this exact system and can be rebuilt on-demand. Copying this information won't be helpful in the cloud or when the data is ever copied back to another Windows volume. Leaving this content behind should not be considered data loss.
/UNILOG:<file name> Writes status to the log file as Unicode. (Overwrites the existing log.)
/L Only for a test run
Files are to be listed only. They won't be copied, not deleted, and not time stamped. Often used with /TEE for console output. Flags from the sample script, like /NP, /NFL, and /NDL, might need to be removed to achieve you properly documented test results.
/Z Use cautiously
Copies files in restart mode. This switch is recommended only in an unstable network environment. It significantly reduces copy performance because of extra logging.
/ZB Use cautiously
Uses restart mode. If access is denied, this option uses backup mode. This option significantly reduces copy performance because of checkpointing.

Important

We recommend using a Windows Server 2022. When using a Windows Server 2019, ensure at the latest patch level or at least OS update KB5005103 is installed. It contains important fixes for certain Robocopy scenarios.

Tip

Check out the Troubleshooting section if RoboCopy is impacting your production environment, reports lots of errors, or isn't progressing as fast as expected.

Phase 4: User cut-over

When you run the RoboCopy command for the first time, your users and applications are still accessing files on the source of your migration and potentially changing them. It's possible that RoboCopy has processed a directory, moved on to the next, and then a user on the source location adds, changes, or deletes a file that will now not be processed in this current RoboCopy run. This behavior is expected.

The first run is about moving the bulk of the churned data to your Azure file share. This first copy can take a while. Check out the Troubleshooting section for more insight into what can affect RoboCopy speeds.

Once the initial run is complete, run the command again.

The second time you run RoboCopy for the same share, it will finish faster, because it only needs to transport changes that happened since the last run. You can run repeated jobs for the same share.

After considering the amount of acceptable downtime, then you need to remove user access to your source shares. You can do that by any steps that prevent users from changing the file and folder structure and content. An example is to point your DFS-Namespace to a non-existing location or change the ACLs on each share.

Run one last RoboCopy round. It will pick up any changes that might have been missed. How long this final step takes depends on the speed of the RoboCopy scan. You can estimate the time (which is equal to your downtime) by measuring how long the previous run took.

In Phase 2, you configured your users to access the share with their identity and should have established a strategy for your users to use established paths to your new Azure file shares (DFS-N).

You can try to run a few of these copies between different source and target shares in parallel. When doing so, keep your network throughput and core to thread count ratio in mind to not overtax the system.

Troubleshoot and optimize

Speed and success rate of a given RoboCopy run will depend on several factors:

  • IOPS on the source and target storage
  • the available network bandwidth between source and target
  • the ability to quickly process files and folders in a namespace
  • the number of changes between RoboCopy runs
  • the size and number of files you need to copy

IOPS and bandwidth considerations

In this category, you need to consider abilities of the source storage, the target storage, and the network connecting them. The maximum possible throughput is determined by the slowest of these three components. Make sure your network infrastructure is configured to support optimal transfer speeds to its best abilities.

Caution

While copying as fast as possible is often most desirable, consider the utilization of your local network and NAS appliance for other, often business-critical tasks.

Copying as fast as possible might not be desirable when there's a risk that the migration could monopolize available resources.

  • Consider when it's best in your environment to run migrations: during the day, off-hours, or during weekends.
  • Also consider networking QoS on a Windows Server to throttle the RoboCopy speed.
  • Avoid unnecessary work for the migration tools.

RoboCopy can insert inter-packet delays by specifying the /IPG:n switch where n is measured in milliseconds between RoboCopy packets. Using this switch can help avoid monopolization of resources on both IO constrained devices, and crowded network links.

/IPG:n can't be used for precise network throttling to a certain Mbps. Use Windows Server Network QoS instead. RoboCopy entirely relies on the SMB protocol for all networking needs. Using SMB is the reason why RoboCopy can't influence the network throughput itself, but it can slow down its use.

A similar line of thought applies to the IOPS observed on the NAS. The cluster size on the NAS volume, packet sizes, and an array of other factors influence the observed IOPS. Introducing inter-packet delay is often the easiest way to control the load on the NAS. Test multiple values, for instance from about 20 milliseconds (n=20) to multiples of that number. Once you introduce a delay, you can evaluate if your other apps can now work as expected. This optimization strategy will allow you to find the optimal RoboCopy speed in your environment.

Processing speed

RoboCopy will traverse the namespace it's pointed to and evaluate each file and folder for copy. Every file will be evaluated during an initial copy and during catch-up copies. For example, repeated runs of RoboCopy /MIR against the same source and target storage locations. These repeated runs are useful to minimize downtime for users and apps, and to improve the overall success rate of files migrated.

We often default to considering bandwidth as the most limiting factor in a migration - and that can be true. But the ability to enumerate a namespace can influence the total time to copy even more for larger namespaces with smaller files. Consider that copying 1 TiB of small files will take considerably longer than copying 1 TiB of fewer but larger files, assuming that all other variables remain the same. Therefore, you may experience slow transfer if you're migrating a large number of small files. This is an expected behavior.

The cause for this difference is the processing power needed to walk through a namespace. RoboCopy supports multi-threaded copies through the /MT:n parameter where n stands for the number of threads to be used. So when provisioning a machine specifically for RoboCopy, consider the number of processor cores and their relationship to the thread count they provide. Most common are two threads per core. The core and thread count of a machine is an important data point to decide what multi-thread values /MT:n you should specify. Also consider how many RoboCopy jobs you plan to run in parallel on a given machine.

More threads will copy our 1 TiB example of small files considerably faster than fewer threads. At the same time, the extra resource investment on our 1 TiB of larger files may not yield proportional benefits. A high thread count will attempt to copy more of the large files over the network simultaneously. This extra network activity increases the probability of getting constrained by throughput or storage IOPS.

During a first RoboCopy into an empty target or a differential run with lots of changed files, you are likely constrained by your network throughput. Start with a high thread count for an initial run. A high thread count, even beyond your currently available threads on the machine, helps saturate the available network bandwidth. Subsequent /MIR runs are progressively impacted by processing items. Fewer changes in a differential run mean less transport of data over the network. Your speed is now more dependent on your ability to process namespace items than to move them over the network link. For subsequent runs, match your thread count value to your processor core count and thread count per core. Consider if cores need to be reserved for other tasks a production server may have.

Tip

Rule of thumb: The first RoboCopy run (that will move a lot of data of a higher-latency network) benefits from over-provisioning the thread count (/MT:n). Subsequent runs will copy fewer differences, and you're more likely to shift from network throughput constrained to compute constrained. Under these circumstances, it's often better to match the RoboCopy thread count to the actually available threads on the machine. Over-provisioning in that scenario can lead to more context shifts in the processor, possibly slowing down your copy.

Avoid unnecessary work

Avoid large-scale changes in your namespace, such as moving files between directories, changing properties at a large scale, or changing directory and file-level permissions (NTFS ACLs). Especially ACL changes can have a high impact because they often have a cascading change effect on files lower in the folder hierarchy. Consequences can be:

  • extended RoboCopy job run time because each file and folder affected by an ACL change needing to be updated
  • reusing data moved earlier may need to be recopied. For instance, more data will need to be copied when folder structures change after files had already been copied earlier. A RoboCopy job can't "play back" a namespace change. The next job must purge the files previously transported to the old folder structure and upload the files in the new folder structure again.

Another important aspect is to use the RoboCopy tool effectively. With the recommended RoboCopy script, you'll create and save a log file for errors. Copy errors can occur - that's normal. These errors often make it necessary to run multiple rounds of a copy tool like RoboCopy: An initial run, say from a NAS to DataBox or a server to an Azure file share, and one or more extra runs with the /MIR switch to catch and retry files that didn't get copied.

You should be prepared to run multiple rounds of RoboCopy against a given namespace scope. Successive runs will finish faster as they have less to copy but are constrained increasingly by the speed of processing the namespace. When you run multiple rounds, you can speed up each round by not having RoboCopy try unreasonably hard to copy everything in a given run. These RoboCopy switches can make a significant difference:

  • /R:n n = how often you retry to copy a failed file and
  • /W:n n = how many seconds to wait between retries

/R:5 /W:5 is a reasonable setting that you can adjust to your liking. In this example, a failed file will be retried five times, with five-second wait time between retries. If the file still fails to copy, the next RoboCopy job will try again. Often files that failed because they are in use or because of timeout issues might eventually be copied successfully this way.

Estimating storage transaction charges

As you begin your migration to Azure Files, RoboCopy copies your files and folders into Azure. Depending on your billing model for Azure Files, transaction charges might apply. See Understanding billing.

If you're using a pay-as-you-go billing model for standard Azure file shares, it might be difficult to estimate the number of transactions your migration will generate.

  • It's not possible to estimate the number of transactions based on the utilized storage capacity of the source. The number of transactions scales with the number of namespace items (files and folder) and their properties that are migrated, not their size. For example, more transactions are required to migrate 1 GiB of small files than 1 GiB of larger files.
  • In order to minimize downtime, you might need to run copy operations several times from source to target. All source and target items are processed during each copy operation, though subsequent runs finish faster. After the initial operations, only the differences introduced between copy runs are transported over the network. It's important to understand that although less data is being transported, the number of transactions required might remain the same.
  • Copying the same file twice might not result in the same number of transactions. Processing an item migrated in a previous copy run might result in only a few read transactions. In contrast, changes to metadata or content between copy runs might require a larger number of transactions to update the target. Each file in your namespace might have unique requirements, resulting in a different number of transactions.

It's advisable to run some initial tests on your own data to better understand how many transactions are incurred. This will give you a better idea of the total number of transactions a file migration might generate.

Next steps

The following articles will help you understand advanced options and best practices.