Post-copy based live migration
(merged in 2.5)
- Name: Dave Gilbert
- Email: email@example.com
- IRC: davidgiluk (oftc/freenode)
- Last updated: 2015-11-24
- Released in: QEMU 2.5
A postcopy implementation that allows migration of guests that have large page change rates (relative to the available bandwidth) to be migrated in a finite time.
VMs of any size running any workload can be migrated.
postcopy means the VM starts running on the destination host as soon as possible, and the RAM from the source host is page faulted into the destination over time. This ensures there is a minimal downtime for the VM as compared to precopy, where the migration can take a lot of time depending on the workload and page dirtying rate of the VM.
- Changes in QEMU, OS support required
- On Linux: userfaultfd in the 4.3 kernel is needed (Now supported on most architectures, tested mainly on x86, some testing on Power and aarch64, s390 support being worked on)
How to use
Enables postcopy mode before the start of migration:
migrate_set_capability x-postcopy-ram on
Start the migration as normal:
Change into postcopy mode; this can be issued any time after the start of migration, for most workloads it's best to wait until one cycle of RAM migration has completed (i.e. the sync count hits 2 in info migrate).
If you're using the HMP (Human Monitor Command), issue:
Or, if you're using the QMP (QEMU Machine Protocol), issue this equivalent command:
NB: When using QMP You might want to use a convenient script like qmp-shell (from QEMU Git source).
Added commands / state
- Migration capability: x-postcopy-ram
- New command: migrate_start_postcopy (HMP) / migrate-start-postcopy (QMP)
- New migration state: postcopy-active
This postcopy implementation uses the Linux 'userfaultfd' kernel mechanisms from Andrea Arcangeli; it's not specific
to postcopy and is designed to allow use with all of the standard kernel features (like transparent huge pages, KSM etc).
It requires Linux 4.3 or newer.
At the start of postcopy mode, all RAM Blocks are registered with 'userfaultfd' so that any accesses to those pages cause the accessing thread to pause.
A separate thread reads messages from the kernel about pages that have been accessed and forwards requests to the source host. The source host
queues those requests and sends the pages ahead of any background page sending (which still carries on during postcopy mode). As pages arrive
on the destination they are placed into memory using new ioctl's that are associated with userfaultfd that cause the page to be copied into the
address space atomically and the paused threads to continue.
The guest page faults are asynchronous, so that multiple page faults can be outstanding at once allowing useful work to continue
inspite of the latency of providing the page.
Where possible the design attempts to build reusable components that other features can reuse.
- 'command' section type for sending migration commands that don't directly reflect guest state; this is used to send messages that move through different phases of postcopy and is expandable for use by others.
- 'return path' a method for the destination to send messages back to the source; used for postcopy page requests, and allows the destination to signal failure back to the source; this is currently supported on TCP and fd (where the fd is socket backed).
- 'unsent map' a bitmap on the source populated with the set of all pages that have not-already been transmitted
- A 'package' command which holds a subset of the migration stream. The state of all non-iterative devices (i.e. disk, timer, CPU etc) are stored in a 'package' and sent as one blob across the migration stream. The destination reads this package off the stream, thus freeing the stream for any page requests that are required while loading the devices themselves.
- 'discard' commands cause some pages that have already been transmitted to be discarded at the start of the postcopy phase. These are pages that have been transmitted and redirtied, or (on Power/aarch64/anything else where host-page size is larger than target-page size) host pages that have been partially transmitted.
- RDMA: we need to find a way to get pages coming via RDMA to appear atomically; probably by copying into a temporary buffer and then being placed.
- File backed memory areas (e.g. HugeTLBFS): Requires kernel support, also needs a mechanism to transmit huge pages as required
- multi-threaded compression: The decompression currently decompresses straight into memory; we need it to place the pages atomically when in postcopy
- The transport in use must support messages in the opposite direction
- optimization - rate limit the background page transmission to reduce the impact on the latency of postcopy page requests.
- Integration with RDMA
- Handle huge pages & mappings from files.