Mapped-ram
Mapped-ram is a new stream format for the RAM section designed to
supplement the existing file: migration and make it compatible
with multifd. This enables parallel migration of a guest’s RAM to
a file.
The core of the feature is to ensure that RAM pages are mapped
directly to offsets in the resulting migration file. This enables the
multifd threads to write exclusively to those offsets even if the
guest is constantly dirtying pages (i.e. live migration). Another
benefit is that the resulting file will have a bounded size, since
pages which are dirtied multiple times will always go to a fixed
location in the file, rather than constantly being added to a
sequential stream. Having the pages at fixed offsets also allows the
usage of O_DIRECT for save/restore of the migration stream as the
pages are ensured to be written respecting O_DIRECT alignment
restrictions (direct-io support not yet implemented).
Usage
On both source and destination, enable the multifd and
mapped-ram capabilities:
migrate_set_capability multifd on
migrate_set_capability mapped-ram on
Use a file: URL for migration:
migrate file:/path/to/migration/file
Mapped-ram migration is best done non-live, i.e. by stopping the VM on the source side before migrating.
Use-cases
The mapped-ram feature was designed for use cases where the migration stream will be directed to a file in the filesystem and not immediately restored on the destination VM [1]. These could be thought of as snapshots. We can further categorize them into live and non-live.
Non-live snapshot
If the use case requires a VM to be stopped before taking a snapshot, that’s the ideal scenario for mapped-ram migration. Not having to track dirty pages, the migration will write the RAM pages to the disk as fast as it can.
Note: if a snapshot is taken of a running VM, but the VM will be stopped after the snapshot by the admin, then consider stopping it right before the snapshot to take benefit of the performance gains mentioned above.
Live snapshot
If the use case requires that the VM keeps running during and after the snapshot operation, then mapped-ram migration can still be used, but will be less performant. Other strategies such as background-snapshot should be evaluated as well. One benefit of mapped-ram in this scenario is portability since background-snapshot depends on async dirty tracking (KVM_GET_DIRTY_LOG) which is not supported outside of Linux.
RAM section format
Instead of having a sequential stream of pages that follow the RAMBlock headers, the dirty pages for a RAMBlock follow its header instead. This ensures that each RAM page has a fixed offset in the resulting migration file.
A bitmap is introduced to track which pages have been written in the migration file. Pages are written at a fixed location for every ramblock. Zero pages are ignored as they’d be zero in the destination migration as well.
Without mapped-ram: With mapped-ram:
--------------------- --------------------------------
| ramblock 1 header | | ramblock 1 header |
--------------------- --------------------------------
| ramblock 2 header | | ramblock 1 mapped-ram header |
--------------------- --------------------------------
| ... | | padding to next 1MB boundary |
--------------------- | ... |
| ramblock n header | --------------------------------
--------------------- | ramblock 1 pages |
| RAM_SAVE_FLAG_EOS | | ... |
--------------------- --------------------------------
| stream of pages | | ramblock 2 header |
| (iter 1) | --------------------------------
| ... | | ramblock 2 mapped-ram header |
--------------------- --------------------------------
| RAM_SAVE_FLAG_EOS | | padding to next 1MB boundary |
--------------------- | ... |
| stream of pages | --------------------------------
| (iter 2) | | ramblock 2 pages |
| ... | | ... |
--------------------- --------------------------------
| ... | | ... |
--------------------- --------------------------------
| RAM_SAVE_FLAG_EOS |
--------------------------------
| ... |
--------------------------------
- where:
ramblock header: the generic information for a ramblock, such as idstr, used_len, etc.
ramblock mapped-ram header: the information added by this feature: bitmap of pages written, bitmap size and offset of pages in the migration file.
Restrictions
Since pages are written to their relative offsets and out of order (due to the memory dirtying patterns), streaming channels such as sockets are not supported. A seekable channel such as a file is required. This can be verified in the QIOChannel by the presence of the QIO_CHANNEL_FEATURE_SEEKABLE.
The improvements brought by this feature apply only to guest physical RAM. Other types of memory such as VRAM are migrated as part of device states.