xref: /openbmc/qemu/docs/devel/migration/vfio.rst (revision 05caa062)
1=====================
2VFIO device migration
3=====================
4
5Migration of virtual machine involves saving the state for each device that
6the guest is running on source host and restoring this saved state on the
7destination host. This document details how saving and restoring of VFIO
8devices is done in QEMU.
9
10Migration of VFIO devices consists of two phases: the optional pre-copy phase,
11and the stop-and-copy phase. The pre-copy phase is iterative and allows to
12accommodate VFIO devices that have a large amount of data that needs to be
13transferred. The iterative pre-copy phase of migration allows for the guest to
14continue whilst the VFIO device state is transferred to the destination, this
15helps to reduce the total downtime of the VM. VFIO devices opt-in to pre-copy
16support by reporting the VFIO_MIGRATION_PRE_COPY flag in the
17VFIO_DEVICE_FEATURE_MIGRATION ioctl.
18
19When pre-copy is supported, it's possible to further reduce downtime by
20enabling "switchover-ack" migration capability.
21VFIO migration uAPI defines "initial bytes" as part of its pre-copy data stream
22and recommends that the initial bytes are sent and loaded in the destination
23before stopping the source VM. Enabling this migration capability will
24guarantee that and thus, can potentially reduce downtime even further.
25
26To support migration of multiple devices that might do P2P transactions between
27themselves, VFIO migration uAPI defines an intermediate P2P quiescent state.
28While in the P2P quiescent state, P2P DMA transactions cannot be initiated by
29the device, but the device can respond to incoming ones. Additionally, all
30outstanding P2P transactions are guaranteed to have been completed by the time
31the device enters this state.
32
33All the devices that support P2P migration are first transitioned to the P2P
34quiescent state and only then are they stopped or started. This makes migration
35safe P2P-wise, since starting and stopping the devices is not done atomically
36for all the devices together.
37
38Thus, multiple VFIO devices migration is allowed only if all the devices
39support P2P migration. Single VFIO device migration is allowed regardless of
40P2P migration support.
41
42A detailed description of the UAPI for VFIO device migration can be found in
43the comment for the ``vfio_device_mig_state`` structure in the header file
44linux-headers/linux/vfio.h.
45
46VFIO implements the device hooks for the iterative approach as follows:
47
48* A ``save_setup`` function that sets up migration on the source.
49
50* A ``load_setup`` function that sets the VFIO device on the destination in
51  _RESUMING state.
52
53* A ``state_pending_estimate`` function that reports an estimate of the
54  remaining pre-copy data that the vendor driver has yet to save for the VFIO
55  device.
56
57* A ``state_pending_exact`` function that reads pending_bytes from the vendor
58  driver, which indicates the amount of data that the vendor driver has yet to
59  save for the VFIO device.
60
61* An ``is_active_iterate`` function that indicates ``save_live_iterate`` is
62  active only when the VFIO device is in pre-copy states.
63
64* A ``save_live_iterate`` function that reads the VFIO device's data from the
65  vendor driver during iterative pre-copy phase.
66
67* A ``switchover_ack_needed`` function that checks if the VFIO device uses
68  "switchover-ack" migration capability when this capability is enabled.
69
70* A ``save_state`` function to save the device config space if it is present.
71
72* A ``save_live_complete_precopy`` function that sets the VFIO device in
73  _STOP_COPY state and iteratively copies the data for the VFIO device until
74  the vendor driver indicates that no data remains.
75
76* A ``load_state`` function that loads the config section and the data
77  sections that are generated by the save functions above.
78
79* ``cleanup`` functions for both save and load that perform any migration
80  related cleanup.
81
82
83The VFIO migration code uses a VM state change handler to change the VFIO
84device state when the VM state changes from running to not-running, and
85vice versa.
86
87Similarly, a migration state change handler is used to trigger a transition of
88the VFIO device state when certain changes of the migration state occur. For
89example, the VFIO device state is transitioned back to _RUNNING in case a
90migration failed or was canceled.
91
92System memory dirty pages tracking
93----------------------------------
94
95A ``log_global_start`` and ``log_global_stop`` memory listener callback informs
96the VFIO dirty tracking module to start and stop dirty page tracking. A
97``log_sync`` memory listener callback queries the dirty page bitmap from the
98dirty tracking module and marks system memory pages which were DMA-ed by the
99VFIO device as dirty. The dirty page bitmap is queried per container.
100
101Currently there are two ways dirty page tracking can be done:
102(1) Device dirty tracking:
103In this method the device is responsible to log and report its DMAs. This
104method can be used only if the device is capable of tracking its DMAs.
105Discovering device capability, starting and stopping dirty tracking, and
106syncing the dirty bitmaps from the device are done using the DMA logging uAPI.
107More info about the uAPI can be found in the comments of the
108``vfio_device_feature_dma_logging_control`` and
109``vfio_device_feature_dma_logging_report`` structures in the header file
110linux-headers/linux/vfio.h.
111
112(2) VFIO IOMMU module:
113In this method dirty tracking is done by IOMMU. However, there is currently no
114IOMMU support for dirty page tracking. For this reason, all pages are
115perpetually marked dirty, unless the device driver pins pages through external
116APIs in which case only those pinned pages are perpetually marked dirty.
117
118If the above two methods are not supported, all pages are perpetually marked
119dirty by QEMU.
120
121By default, dirty pages are tracked during pre-copy as well as stop-and-copy
122phase. So, a page marked as dirty will be copied to the destination in both
123phases. Copying dirty pages in pre-copy phase helps QEMU to predict if it can
124achieve its downtime tolerances. If QEMU during pre-copy phase keeps finding
125dirty pages continuously, then it understands that even in stop-and-copy phase,
126it is likely to find dirty pages and can predict the downtime accordingly.
127
128QEMU also provides a per device opt-out option ``pre-copy-dirty-page-tracking``
129which disables querying the dirty bitmap during pre-copy phase. If it is set to
130off, all dirty pages will be copied to the destination in stop-and-copy phase
131only.
132
133System memory dirty pages tracking when vIOMMU is enabled
134---------------------------------------------------------
135
136With vIOMMU, an IO virtual address range can get unmapped while in pre-copy
137phase of migration. In that case, the unmap ioctl returns any dirty pages in
138that range and QEMU reports corresponding guest physical pages dirty. During
139stop-and-copy phase, an IOMMU notifier is used to get a callback for mapped
140pages and then dirty pages bitmap is fetched from VFIO IOMMU modules for those
141mapped ranges. If device dirty tracking is enabled with vIOMMU, live migration
142will be blocked.
143
144Flow of state changes during Live migration
145===========================================
146
147Below is the state change flow during live migration for a VFIO device that
148supports both precopy and P2P migration. The flow for devices that don't
149support it is similar, except that the relevant states for precopy and P2P are
150skipped.
151The values in the parentheses represent the VM state, the migration state, and
152the VFIO device state, respectively.
153
154Live migration save path
155------------------------
156
157::
158
159                           QEMU normal running state
160                           (RUNNING, _NONE, _RUNNING)
161                                      |
162                     migrate_init spawns migration_thread
163            Migration thread then calls each device's .save_setup()
164                          (RUNNING, _SETUP, _PRE_COPY)
165                                      |
166                         (RUNNING, _ACTIVE, _PRE_COPY)
167  If device is active, get pending_bytes by .state_pending_{estimate,exact}()
168       If total pending_bytes >= threshold_size, call .save_live_iterate()
169                Data of VFIO device for pre-copy phase is copied
170      Iterate till total pending bytes converge and are less than threshold
171                                      |
172       On migration completion, the vCPUs and the VFIO device are stopped
173              The VFIO device is first put in P2P quiescent state
174                    (FINISH_MIGRATE, _ACTIVE, _PRE_COPY_P2P)
175                                      |
176                Then the VFIO device is put in _STOP_COPY state
177                     (FINISH_MIGRATE, _ACTIVE, _STOP_COPY)
178         .save_live_complete_precopy() is called for each active device
179      For the VFIO device, iterate in .save_live_complete_precopy() until
180                               pending data is 0
181                                      |
182                     (POSTMIGRATE, _COMPLETED, _STOP_COPY)
183            Migraton thread schedules cleanup bottom half and exits
184                                      |
185                           .save_cleanup() is called
186                        (POSTMIGRATE, _COMPLETED, _STOP)
187
188Live migration resume path
189--------------------------
190
191::
192
193             Incoming migration calls .load_setup() for each device
194                          (RESTORE_VM, _ACTIVE, _STOP)
195                                      |
196     For each device, .load_state() is called for that device section data
197                        (RESTORE_VM, _ACTIVE, _RESUMING)
198                                      |
199  At the end, .load_cleanup() is called for each device and vCPUs are started
200              The VFIO device is first put in P2P quiescent state
201                        (RUNNING, _ACTIVE, _RUNNING_P2P)
202                                      |
203                           (RUNNING, _NONE, _RUNNING)
204
205Postcopy
206========
207
208Postcopy migration is currently not supported for VFIO devices.
209