On Tue, 16 Oct 2018 23:42:35 +0530 Kirti Wankhede <kwankh...@nvidia.com> wrote:
> - Added vfio_device_migration_info structure to use interact with vendor > driver. > - Different flags are used to get or set migration related information > from/to vendor driver. > Flag VFIO_MIGRATION_PROBE: To query if feature is supported > Flag VFIO_MIGRATION_GET_REGION: To get migration region info > Flag VFIO_MIGRATION_SET_STATE: To convey device state in vendor driver > Flag VFIO_MIGRATION_GET_PENDING: To get pending bytes yet to be migrated > from vendor driver > Flag VFIO_MIGRATION_GET_BUFFER: On this flag, vendor driver should write > data to migration region and return number of bytes written in the region > Flag VFIO_MIGRATION_SET_BUFFER: In migration resume path, user space app > writes to migration region and communicates it to vendor driver with > this ioctl with this flag. > Flag VFIO_MIGRATION_GET_DIRTY_PFNS: Get bitmap of dirty pages from vendor > driver from given start address > > - Added enum for possible device states. > > Signed-off-by: Kirti Wankhede <kwankh...@nvidia.com> > Reviewed-by: Neo Jia <c...@nvidia.com> > --- > linux-headers/linux/vfio.h | 91 > ++++++++++++++++++++++++++++++++++++++++++++++ > 1 file changed, 91 insertions(+) > > diff --git a/linux-headers/linux/vfio.h b/linux-headers/linux/vfio.h > index 3615a269d378..8e9045ed9aa8 100644 > --- a/linux-headers/linux/vfio.h > +++ b/linux-headers/linux/vfio.h > @@ -602,6 +602,97 @@ struct vfio_device_ioeventfd { > > #define VFIO_DEVICE_IOEVENTFD _IO(VFIO_TYPE, VFIO_BASE + 16) > > +/** > + * VFIO_DEVICE_MIGRATION_INFO - _IOW(VFIO_TYPE, VFIO_BASE + 17, > + * struct vfio_device_migration_info) This is quite a bit more than an "INFO" ioctl. > + * Flag VFIO_MIGRATION_PROBE: > + * To query if feature is supported > + * > + * Flag VFIO_MIGRATION_GET_REGION: > + * To get migration region info > + * region_index [output] : region index to be used for migration region > + * size [output]: size of migration region Of course the region migration region can describe itself as being used for migration, so this is unnecessary. The presence of that region could also negate the need for a probe. > + * > + * Flag VFIO_MIGRATION_SET_STATE: > + * To set device state in vendor driver > + * device_state [input] : User space app sends device state to vendor > + * driver on state change Valid states are the enum defined below, correct? Does setting STOPNCOPY_ACTIVE stop any state change of the device or is that expected to happen through other means? What are the allowable state transitions? How many bits in flags is a user allowed to set at once? > + * Flag VFIO_MIGRATION_GET_PENDING: > + * To get pending bytes yet to be migrated from vendor driver > + * threshold_size [Input] : threshold of buffer in User space app. > + * pending_precopy_only [output] : pending data which must be migrated > in > + * precopy phase or in stopped state, in other words - before target > + * vm start > + * pending_compatible [output] : pending data which may be migrated in > any > + * phase > + * pending_postcopy_only [output] : pending data which must be migrated > in > + * postcopy phase or in stopped state, in other words - after > source > + * vm stop > + * Sum of pending_precopy_only, pending_compatible and > + * pending_postcopy_only is the whole amount of pending data. What's the significance of the provided threshold, are the pending bytes limited to threshold size? It makes me nervous to define a kernel API in terms of the internal API of a userspace program that can change. I wonder if it makes sense to define these in terms of the state of the devices, pending initial data, runtime data, post-offline data. > + * > + * Flag VFIO_MIGRATION_GET_BUFFER: > + * On this flag, vendor driver should write data to migration > region and > + * return number of bytes written in the region. > + * bytes_written [output] : number of bytes written in > migration buffer by > + * vendor driver Does the data the user gets here depend on the device state set earlier? For example the user gets pending_precopy_only data while PRECOPY_ACTIVE is the device state and pending_postcopy_only data in STOPNCOPY_ACTIVE? The user should continue to call GET_BUFFER in a given state until the associated pending field reaches zero? Jumping between the region and ioctl is rather awkward. > + * > + * Flag VFIO_MIGRATION_SET_BUFFER > + * In migration resume path, user space app writes to migration > region and > + * communicates it to vendor driver with this ioctl with this > flag. > + * bytes_written [Input] : number of bytes written in migration > buffer by > + * user space app. > + * > + * Flag VFIO_MIGRATION_GET_DIRTY_PFNS > + * Get bitmap of dirty pages from vendor driver from given > start address. > + * start_addr [Input] : start address > + * pfn_count [Input] : Total pfn count from start_addr for > which dirty > + * bitmap is requested > + * dirty_bitmap [Output] : bitmap memory allocated by user space > + * application, vendor driver should return the bitmap > with bits set > + * only for pages to be marked dirty. > + * Return: 0 on success, -errno on failure. > + */ > + > +struct vfio_device_migration_info { > + __u32 argsz; > + __u32 flags; > +#define VFIO_MIGRATION_PROBE (1 << 0) > +#define VFIO_MIGRATION_GET_REGION (1 << 1) > +#define VFIO_MIGRATION_SET_STATE (1 << 2) > +#define VFIO_MIGRATION_GET_PENDING (1 << 3) > +#define VFIO_MIGRATION_GET_BUFFER (1 << 4) > +#define VFIO_MIGRATION_SET_BUFFER (1 << 5) > +#define VFIO_MIGRATION_GET_DIRTY_PFNS (1 << 6) > + __u32 region_index; /* region index */ > + __u64 size; /* size */ > + __u32 device_state; /* VFIO device state */ We'd need to swap device_state and size for alignment or else this struct could vary by compiler. > + __u64 pending_precopy_only; > + __u64 pending_compatible; > + __u64 pending_postcopy_only; > + __u64 threshold_size; > + __u64 bytes_written; > + __u64 start_addr; > + __u64 pfn_count; > + __u8 dirty_bitmap[]; > +}; > + > +enum { > + VFIO_DEVICE_STATE_NONE, > + VFIO_DEVICE_STATE_RUNNING, > + VFIO_DEVICE_STATE_MIGRATION_SETUP, > + VFIO_DEVICE_STATE_MIGRATION_PRECOPY_ACTIVE, > + VFIO_DEVICE_STATE_MIGRATION_STOPNCOPY_ACTIVE, > + VFIO_DEVICE_STATE_MIGRATION_SAVE_COMPLETED, > + VFIO_DEVICE_STATE_MIGRATION_RESUME, > + VFIO_DEVICE_STATE_MIGRATION_RESUME_COMPLETED, > + VFIO_DEVICE_STATE_MIGRATION_FAILED, > + VFIO_DEVICE_STATE_MIGRATION_CANCELLED, > +}; > + > +#define VFIO_DEVICE_MIGRATION_INFO _IO(VFIO_TYPE, VFIO_BASE + 17) > + I'm not entirely sure what this ioctl buys us that we can't do with a region alone. For example we could define a migration region as: struct vfio_region_migration { __u32 device_state; __u32 data_offset; __u64 data_size; __u64 pending_pre; __u64 pending_runtime; __u64 pending_post; __u64 bytes_available; __u64 bytes_written; }; A sparse mmap capability in the region could define whether the data area supports mmap, the above defined registers would only have read/write access. The user can write device_state the same as the ioctl would set it. The data_offset and size describe the offset in the region where migration data is relayed and the size of that area. Pending fields are as you have above, though I've omitted the threshold because I don't understand it. The user reading bytes_available is the same as calling GET_BUFFER, bytes_written the same as SET_BUFFER. I've left out the dirty bitmap here, as it's a little less obvious to me how it would work. It could be a stand-alone ioctl, it could be implemented as another region, or it could simply be a different offset within this region. The dirty bitmap start address could simply be calculated as the offset into that region where a pread begins and the extent is the size of that pread. With a bit per page, we're only looking at a 32MB region per 1TB of guest physical address space, so it doesn't seem too terrible even if guest memory is sparse. Maybe the extremes are still problematic though, but if it were part of the same region above we could solve that with another register written by the user to indicate the base offset of the dirty bitmap window. For example if the window is 32MB and page size 4k then it can index 1TB and the user would write 0 (default) to the register for pfns from 0 to (1TB - 1), 1 for pfns from 1TB to (2TB - 1), etc. I don't see that this interface does anything to address the compatibility concerns that were discussed in the previous iterations from Intel though, nor is it documented exactly where and how a vendor driver would indicate a migration failure if it had its own internal consistency or compatibility checks fail. Thanks, Alex