Difference between revisions of "Userfaultfd"

From CRIU
Jump to navigation Jump to search
m
 
(14 intermediate revisions by 4 users not shown)
Line 1: Line 1:
Collected on this page is the design notes about supporting userfaultfd in CRIU
+
This article describes usage of userfaultfd for lazy restore and lazy migration in CRIU.
 +
 
 +
== Background ==
 +
The [http://man7.org/linux/man-pages/man2/userfaultfd.2.html userfaultfd] mechanism is designed to allow user-space paging. Its initial implementation merged in Linux 4.3 was designed for KVM/QEMU use-case and lacked some functionality necessary for CRIU. In Linux 4.11 the userfaultfd was extended with so-called "non-cooperative" mode, that allows, at least in theory, lazy (or post-copy) restore in CRIU.
  
 
== Concepts ==
 
== Concepts ==
  
* Only MAP_PRIVATE | MAP_ANONYMOUS will be supported in the 1st version due to kernel constraints
+
* The <code>restore</code> action accepts yet another API switch: option <code>--lazy-pages</code>. In this mode, <code>restore</code> skips injection of lazy pages into the processes address space, but rather registers lazy memory areas with userfaultfd.
* The <code>restore</code> action should accept yet another API switch: option <code>--lazy-pages</code>
+
* The lazy pages are completely handled by dedicated <code>lazy-pages</code> daemon. The daemon receives userfault file descriptors from <code>restore</code> via UNIX socket. The userfault file descriptors allow reception of page-fault and other events and resolution of these events by the daemon.
 +
* For the migration case, the <code>dump</code> action also accepts API switch: option <code>--lazy-pages</code>. When this option is used, the <code>dump</code> keeps the memory pages and allows the <code>lazy-pages</code> daemon to request these pages via TCP connection.
  
 
[[File:Criu-memory-wflow.png]]
 
[[File:Criu-memory-wflow.png]]
Line 10: Line 14:
 
=== Daemon ===
 
=== Daemon ===
  
Tasks after restore should have lazy VMAs being backed by userfaultfd, the fd itself should be sent before resume to CRIU (daemon?) and closed. This is CRIU who will monitor the UFFD events and repopulate the tasks address space. It should be able to get pages from both -- remote and local images.
+
Tasks after restore have lazy VMAs registered with userfaultfd, the fd itself is sent before resume to <code>lazy-pages</code> daemon and closed. The daemon monitors the UFFD events and repopulates the tasks address space. The <code>lazy-pages</code> daemon can get pages either from images (both local and remote) or directly from the remote side <code>dump</code>.
 +
 
 +
When the restored task accesses a missing memory page, it causes a page fault. The <code>lazy-pages</code> daemon receives the page fault notification and resolves it by populating the faulting task memory. If there were no page faults for some time, the daemon copies the task's remaining memory pages in the background.
 +
 
 +
==== Local images ====
 +
 
 +
The daemon uses local page-read engine to read pages from images.
 +
 
 +
==== Remote images ====
 +
 
 +
* The [[page server]] is run on the remote side with <code>--lazy-pages</code> option.
 +
* The lazy-pages daemon connects to the remote [[page server]] with <code>--page-server</code> option. The <code>--address</code> and <code>--port</code> options allow setting of IP address and port of the listening [[page server]].
 +
* Current protocol allows the lazy-pages daemon to request several continuous pages.
  
=== Local images ===
+
==== Migration ====
 +
* The <code>dump</code> collects the pages into pipes and starts the [[page server]] in a mode that allows <code>lazy-pages</code> daemon to connect to it and request the memory pages
 +
* When the restored task accesses a missing memory page, the <code>lazy-pages</code> daemon request the page from the [[page server]] running on the dump side
 +
* After the page is received, the <code>lazy-pages</code> daemon injects it into the task's address space using userfautlfd
  
The daemon should just use local page-read engine and read pages from images.
+
== Limitations ==
  
=== Remote images ===
+
* Currently only MAP_PRIVATE | MAP_ANONYMOUS is supported. Newer kernels (4.11+) allow userfaultfd for hugetlbfs and shared memory, yet to be implemented in CRIU.
 +
* Userfault is known not to map one page into two places. Thus -- COW-ed pages will get COW-ed.
  
* The page-read engine should be patched to learn how to talk to the remote host ([[page server]] with --page-server option?) on the other end.
+
== See also ==
* The source node should get pages from tasks dumped and send them out on the destination node.
 
* Protocol should include out-of-order pages and background pages pushing (sending them before demand from the process).
 
  
 +
* [[Disk-less migration]]
 +
* [[Lazy migration]]
  
 
[[Category:Memory]]
 
[[Category:Memory]]
[[Category:Plans]]
+
[[Category:New features]]
[[Category:Development]]
+
[[Category:Under the hood]]

Latest revision as of 04:39, 24 October 2019

This article describes usage of userfaultfd for lazy restore and lazy migration in CRIU.

Background[edit]

The userfaultfd mechanism is designed to allow user-space paging. Its initial implementation merged in Linux 4.3 was designed for KVM/QEMU use-case and lacked some functionality necessary for CRIU. In Linux 4.11 the userfaultfd was extended with so-called "non-cooperative" mode, that allows, at least in theory, lazy (or post-copy) restore in CRIU.

Concepts[edit]

  • The restore action accepts yet another API switch: option --lazy-pages. In this mode, restore skips injection of lazy pages into the processes address space, but rather registers lazy memory areas with userfaultfd.
  • The lazy pages are completely handled by dedicated lazy-pages daemon. The daemon receives userfault file descriptors from restore via UNIX socket. The userfault file descriptors allow reception of page-fault and other events and resolution of these events by the daemon.
  • For the migration case, the dump action also accepts API switch: option --lazy-pages. When this option is used, the dump keeps the memory pages and allows the lazy-pages daemon to request these pages via TCP connection.

Criu-memory-wflow.png

Daemon[edit]

Tasks after restore have lazy VMAs registered with userfaultfd, the fd itself is sent before resume to lazy-pages daemon and closed. The daemon monitors the UFFD events and repopulates the tasks address space. The lazy-pages daemon can get pages either from images (both local and remote) or directly from the remote side dump.

When the restored task accesses a missing memory page, it causes a page fault. The lazy-pages daemon receives the page fault notification and resolves it by populating the faulting task memory. If there were no page faults for some time, the daemon copies the task's remaining memory pages in the background.

Local images[edit]

The daemon uses local page-read engine to read pages from images.

Remote images[edit]

  • The page server is run on the remote side with --lazy-pages option.
  • The lazy-pages daemon connects to the remote page server with --page-server option. The --address and --port options allow setting of IP address and port of the listening page server.
  • Current protocol allows the lazy-pages daemon to request several continuous pages.

Migration[edit]

  • The dump collects the pages into pipes and starts the page server in a mode that allows lazy-pages daemon to connect to it and request the memory pages
  • When the restored task accesses a missing memory page, the lazy-pages daemon request the page from the page server running on the dump side
  • After the page is received, the lazy-pages daemon injects it into the task's address space using userfautlfd

Limitations[edit]

  • Currently only MAP_PRIVATE | MAP_ANONYMOUS is supported. Newer kernels (4.11+) allow userfaultfd for hugetlbfs and shared memory, yet to be implemented in CRIU.
  • Userfault is known not to map one page into two places. Thus -- COW-ed pages will get COW-ed.

See also[edit]