On Thu, 19 Dec 2019 21:38:44 +0530 Kirti Wankhede <kwankhede@xxxxxxxxxx> wrote: > On 12/18/2019 12:13 AM, Alex Williamson wrote: > > On Tue, 17 Dec 2019 11:58:44 +0530 > > Kirti Wankhede <kwankhede@xxxxxxxxxx> wrote: > > > >> On 12/17/2019 4:14 AM, Alex Williamson wrote: > >>> On Tue, 17 Dec 2019 01:51:36 +0530 > >>> Kirti Wankhede <kwankhede@xxxxxxxxxx> wrote: > >>> > >>>> - Defined MIGRATION region type and sub-type. > >>>> > >>>> - Defined vfio_device_migration_info structure which will be placed at 0th > >>>> offset of migration region to get/set VFIO device related information. > >>>> Defined members of structure and usage on read/write access. > >>>> > >>>> - Defined device states and added state transition details in the comment. > >>>> > >>>> - Added sequence to be followed while saving and resuming VFIO device state > >>>> > >>>> Signed-off-by: Kirti Wankhede <kwankhede@xxxxxxxxxx> > >>>> Reviewed-by: Neo Jia <cjia@xxxxxxxxxx> > >>>> --- > >>>> include/uapi/linux/vfio.h | 180 ++++++++++++++++++++++++++++++++++++++++++++++ > >>>> 1 file changed, 180 insertions(+) > >>>> > >>>> diff --git a/include/uapi/linux/vfio.h b/include/uapi/linux/vfio.h > >>>> index 9e843a147ead..a0817ba267c1 100644 > >>>> --- a/include/uapi/linux/vfio.h > >>>> +++ b/include/uapi/linux/vfio.h > >>>> @@ -305,6 +305,7 @@ struct vfio_region_info_cap_type { > >>>> #define VFIO_REGION_TYPE_PCI_VENDOR_MASK (0xffff) > >>>> #define VFIO_REGION_TYPE_GFX (1) > >>>> #define VFIO_REGION_TYPE_CCW (2) > >>>> +#define VFIO_REGION_TYPE_MIGRATION (3) > >>>> > >>>> /* sub-types for VFIO_REGION_TYPE_PCI_* */ > >>>> > >>>> @@ -379,6 +380,185 @@ struct vfio_region_gfx_edid { > >>>> /* sub-types for VFIO_REGION_TYPE_CCW */ > >>>> #define VFIO_REGION_SUBTYPE_CCW_ASYNC_CMD (1) > >>>> > >>>> +/* sub-types for VFIO_REGION_TYPE_MIGRATION */ > >>>> +#define VFIO_REGION_SUBTYPE_MIGRATION (1) > >>>> + > >>>> +/* > >>>> + * Structure vfio_device_migration_info is placed at 0th offset of > >>>> + * VFIO_REGION_SUBTYPE_MIGRATION region to get/set VFIO device related migration > >>>> + * information. Field accesses from this structure are only supported at their > >>>> + * native width and alignment, otherwise the result is undefined and vendor > >>>> + * drivers should return an error. > >>>> + * > >>>> + * device_state: (read/write) > >>>> + * To indicate vendor driver the state VFIO device should be transitioned > >>>> + * to. If device state transition fails, write on this field return error. > >>>> + * It consists of 3 bits: > >>>> + * - If bit 0 set, indicates _RUNNING state. When its clear, that indicates > >>> > >>> s/its/it's/ > >>> > >>>> + * _STOP state. When device is changed to _STOP, driver should stop > >>>> + * device before write() returns. > >>>> + * - If bit 1 set, indicates _SAVING state. When set, that indicates driver > >>>> + * should start gathering device state information which will be provided > >>>> + * to VFIO user space application to save device's state. > >>>> + * - If bit 2 set, indicates _RESUMING state. When set, that indicates > >>>> + * prepare to resume device, data provided through migration region > >>>> + * should be used to resume device. > >>>> + * Bits 3 - 31 are reserved for future use. User should perform > >>>> + * read-modify-write operation on this field. > >>>> + * > >>>> + * +------- _RESUMING > >>>> + * |+------ _SAVING > >>>> + * ||+----- _RUNNING > >>>> + * ||| > >>>> + * 000b => Device Stopped, not saving or resuming > >>>> + * 001b => Device running state, default state > >>>> + * 010b => Stop Device & save device state, stop-and-copy state > >>>> + * 011b => Device running and save device state, pre-copy state > >>>> + * 100b => Device stopped and device state is resuming > >>>> + * 101b => Invalid state > >>> > >>> Eventually this would be intended for post-copy, if supported by the > >>> device, right? > >>> > >> > >> No, as per Yan mentioned in earlier version, _RESUMING + _RUNNING can't > >> be used for post-copy. New flag will be required for post-copy. > >> > >> https://www.mail-archive.com/qemu-devel@xxxxxxxxxx/msg658768.html > >> > >>>> + * 110b => Invalid state > >>>> + * 111b => Invalid state > >>>> + * > >>>> + * State transitions: > >>>> + * > >>>> + * _RESUMING _RUNNING Pre-copy Stop-and-copy _STOP > >>>> + * (100b) (001b) (011b) (010b) (000b) > >>>> + * 0. Running or Default state > >>>> + * | > >>>> + * > >>>> + * 1. Normal Shutdown > >>> > >>> Optional, userspace is under no obligation. > >>> > >>>> + * |------------------------------------->| > >>>> + * > >>>> + * 2. Save state or Suspend > >>>> + * |------------------------->|---------->| > >>>> + * > >>>> + * 3. Save state during live migration > >>>> + * |----------->|------------>|---------->| > >>>> + * > >>>> + * 4. Resuming > >>>> + * |<---------| > >>>> + * > >>>> + * 5. Resumed > >>>> + * |--------->| > >>>> + * > >>>> + * 0. Default state of VFIO device is _RUNNNG when VFIO application starts. > >>>> + * 1. During normal VFIO application shutdown, vfio device state changes > >>>> + * from _RUNNING to _STOP. > >>> > >>> We cannot impose this requirement on existing userspace. Userspace may > >>> perform this action, but they are not required to and the vendor driver > >>> must not require it. > >> > >> Updated comment. > >> > >>> > >>>> + * 2. When VFIO application save state or suspend application, VFIO device > >>>> + * state transition is from _RUNNING to stop-and-copy state and then to > >>>> + * _STOP. > >>>> + * On state transition from _RUNNING to stop-and-copy, driver must > >>>> + * stop device, save device state and send it to application through > >>>> + * migration region. > >>>> + * On _RUNNING to stop-and-copy state transition failure, application should > >>>> + * set VFIO device state to _RUNNING. > >>> > >>> A state transition failure means that the user's write to device_state > >>> failed, so is it the user's responsibility to set the next state? > >> > >> Right. > > > > If a transition failure occurs, ie. errno from write(2), what value is > > reported by a read(2) of device_state in the interim between the failure > > and a next state written by the user? > > Since state transition has failed, driver should return previous state. > > > If this is a valid state, > > wouldn't it be reasonable for the user to assume the device is already > > operating in that state? This ^^^ > If it's an invalid state, do we need to > > define the use cases for those invalid states? If the user needs to > > set the state back to _RUNNING, that suggests the device might be > > stopped, which has implications beyond the migration state. > > > > Not necessarily stopped. For example, during live migration: > > * _RESUMING _RUNNING Pre-copy Stop-and-copy _STOP > * (100b) (001b) (011b) (010b) (000b) > * > * 3. Save state during live migration > * |----------->|------------>|---------->| > > on any state transition failure, user should set _RUNNING state. > pre-copy (011b) -> stop-and-copy(010b) =====> _SAVING flag is cleared > and device returned back to _RUNNING. > Stop-and-copy(010b) -> STOP (000b) ====> device is already stopped. IMO, the user may modify the state, but the vendor driver should report the current state of the device via device_state, which the user may read after a transition error occurs. The spec lacks a provision for indicating the device is in a non-functional state. > >>> Why > >>> is it necessarily _RUNNING vs _STOP? > >>> > >> > >> While changing From pre-copy to stop-and-copy transition, device is > >> still running, only saving of device state started. Now if transition to > >> stop-and-copy fails, from user point of view application or VM is still > >> running, device state should be set to _RUNNING so that whatever the > >> application/VM is running should continue at source. > > > > Seems it's the users discretion whether to consider this continuable or > > fatal, the vfio interface specification should support a given usage > > model, not prescribe it. > > > > Updating comment. > > >>>> + * 3. In VFIO application live migration, state transition is from _RUNNING > >>>> + * to pre-copy to stop-and-copy to _STOP. > >>>> + * On state transition from _RUNNING to pre-copy, driver should start > >>>> + * gathering device state while application is still running and send device > >>>> + * state data to application through migration region. > >>>> + * On state transition from pre-copy to stop-and-copy, driver must stop > >>>> + * device, save device state and send it to application through migration > >>>> + * region. > >>>> + * On any failure during any of these state transition, VFIO device state > >>>> + * should be set to _RUNNING. > >>> > >>> Same comment as above regarding next state on failure. > >>> > >> > >> If application or VM migration fails, it should continue to run at > >> source. In case of VM, guest user isn't aware of migration, and from his > >> point VM should be running. > > > > vfio is not prescribing the migration semantics to userspace, it's > > presenting an interface that support the user semantics. Therefore, > > while it's useful to understand the expected usage model, I think we > > also need a mechanism that the user can always determine the > > device_state after a fault > > If state transition fails, device is in previous state and driver should > return previous state Then why is it stated that the user needs to set the _RUNNING state? It's the user's choice. But I do think we're lacking a state to indicate an internal fault. > > and allowable state transitions independent > > of the expected usage model. > > Do you mean to define array of ['from','to'], same as runstate > transition array in QEMU? > static const RunStateTransition runstate_transitions_def[] I'm thinking that independent of expected QEMU usage models, are there any invalid transitions or is every state reachable from every other state. I'm afraid this design is so focused on a specific usage model that vendor drivers are going to fall over if the user invokes a transition outside of those listed above. If there are invalid transitions, those should be listed so they can be handled consistently. If there are no invalid transitions, it should be noted in the spec to encourage vendor drivers to expect this. > > For example, I think a user should always > > be allowed to transition a device to stopped regardless of the expected > > migration flow. An error might have occurred elsewhere and we want to > > stop everything for debugging. I think it's also allowable to switch > > directly from running to stop-and-copy, for example to save and resume > > a VM offline. > > > >>> Also, it seems like it's the vendor driver's discretion to actually > >>> provide data during the pre-copy phase. As we've defined it, the > >>> vendor driver needs to participate in the migration region regardless, > >>> they might just always report no pending_bytes until we enter > >>> stop-and-copy. > >>> > >> > >> Yes. And if pending_bytes are reported as 0 in pre-copy by vendor driver > >> then QEMU doesn't reiterate for that device. > > > > Maybe we can state that as the expected mechanism to avoid a vendor > > driver trying to invent alternative means, ex. failing transition to > > pre-copy, requesting new flags, etc. > > > > Isn't Sequence to be followed below sufficient to state that? I think we understand it because we've been discussing it so long, but without that background it could be subtle. > >>>> + * 4. To start resuming phase, VFIO device state should be transitioned from > >>>> + * _RUNNING to _RESUMING state. > >>>> + * In _RESUMING state, driver should use received device state data through > >>>> + * migration region to resume device. > >>>> + * On failure during this state transition, application should set _RUNNING > >>>> + * state. > >>> > >>> Same comment regarding setting next state after failure. > >> > >> If device couldn't be transitioned to _RESUMING, then it should be set > >> to default state, that is _RUNNING. > >> > >>> > >>>> + * 5. On providing saved device data to driver, appliation should change state > >>>> + * from _RESUMING to _RUNNING. > >>>> + * On failure to transition to _RUNNING state, VFIO application should reset > >>>> + * the device and set _RUNNING state so that device doesn't remain in unknown > >>>> + * or bad state. On reset, driver must reset device and device should be > >>>> + * available in default usable state. > >>> > >>> Didn't we discuss that the reset ioctl should return the device to the > >>> initial state, including the transition to _RUNNING? > >> > >> Yes, that's default usable state, rewording it to initial state. > >> > >>> Also, as above, > >>> it's the user write that triggers the failure, this register is listed > >>> as read-write, so what value does the vendor driver report for the > >>> state when read after a transition failure? Is it reported as _RESUMING > >>> as it was prior to the attempted transition, or may the invalid states > >>> be used by the vendor driver to indicate the device is broken? > >>> > >> > >> If transition as failed, device should report its previous state and > >> reset device should bring back to usable _RUNNING state. > > > > If device_state reports previous state then user should reasonably > > infer that the device is already in that sate without a need for them > > to set it, IMO. > > But if there is any error in read()/write() then user should device > which next state device should be put in, which would be different that > previous state. That's a different answer than telling the user the next state should be _RUNNING. > >>>> + * > >>>> + * pending bytes: (read only) > >>>> + * Number of pending bytes yet to be migrated from vendor driver > >>>> + * > >>>> + * data_offset: (read only) > >>>> + * User application should read data_offset in migration region from where > >>>> + * user application should read device data during _SAVING state or write > >>>> + * device data during _RESUMING state. See below for detail of sequence to > >>>> + * be followed. > >>>> + * > >>>> + * data_size: (read/write) > >>>> + * User application should read data_size to get size of data copied in > >>>> + * bytes in migration region during _SAVING state and write size of data > >>>> + * copied in bytes in migration region during _RESUMING state. > >>>> + * > >>>> + * Migration region looks like: > >>>> + * ------------------------------------------------------------------ > >>>> + * |vfio_device_migration_info| data section | > >>>> + * | | /////////////////////////////// | > >>>> + * ------------------------------------------------------------------ > >>>> + * ^ ^ > >>>> + * offset 0-trapped part data_offset > >>>> + * > >>>> + * Structure vfio_device_migration_info is always followed by data section in > >>>> + * the region, so data_offset will always be non-0. Offset from where data is > >>>> + * copied is decided by kernel driver, data section can be trapped or mapped > >>>> + * or partitioned, depending on how kernel driver defines data section. > >>>> + * Data section partition can be defined as mapped by sparse mmap capability. > >>>> + * If mmapped, then data_offset should be page aligned, where as initial section > >>>> + * which contain vfio_device_migration_info structure might not end at offset > >>>> + * which is page aligned. The user is not required to access via mmap regardless > >>>> + * of the region mmap capabilities. > >>>> + * Vendor driver should decide whether to partition data section and how to > >>>> + * partition the data section. Vendor driver should return data_offset > >>>> + * accordingly. > >>>> + * > >>>> + * Sequence to be followed for _SAVING|_RUNNING device state or pre-copy phase > >>>> + * and for _SAVING device state or stop-and-copy phase: > >>>> + * a. read pending_bytes, indicates start of new iteration to get device data. > >>>> + * If there was previous iteration, then this read operation indicates > >>>> + * previous iteration is done. If pending_bytes > 0, go through below steps. > >>>> + * b. read data_offset, indicates kernel driver to make data available through > >>>> + * data section. Kernel driver should return this read operation only after > >>>> + * data is available from (region + data_offset) to (region + data_offset + > >>>> + * data_size). > >>>> + * c. read data_size, amount of data in bytes available through migration > >>>> + * region. > >>>> + * d. read data of data_size bytes from (region + data_offset) from migration > >>>> + * region. > >>>> + * e. process data. > >>>> + * f. Loop through a to e. > >>> > >>> It seems we always need to end an iteration by reading pending_bytes to > >>> signal to the vendor driver to release resources, so should the end of > >>> the loop be: > >>> > >>> e. Read pending_bytes > >>> f. Goto b. or optionally restart next iteration at a. > >>> > >>> I think this is defined such that reading data_offset commits resources > >>> and reading pending_bytes frees them, allowing userspace to restart at > >>> reading pending_bytes with no side-effects. Therefore reading > >>> pending_bytes repeatedly is supported. Is the same true for > >>> data_offset and data_size? It seems reasonable that the vendor driver > >>> can simply return offset and size for the current buffer if the user > >>> reads these more than once. > >>> > >> > >> Right. > > > > Can we add that to the spec? > > > > ok. > > >>> How is a protocol or device error signaled? For example, we can have a > >>> user error where they read data_size before data_offset. Should the > >>> vendor driver generate a fault reading data_size in this case. We can > >>> also have internal errors in the vendor driver, should the vendor > >>> driver use a special errno or update device_state autonomously to > >>> indicate such an error? > >> > >> If there is any error during the sequence, vendor driver can return > >> error code for next read/write operation, that will terminate the loop > >> and migration would fail. > > > > Please add to spec. > > > > Ok > > >>> I believe it's also part of the intended protocol that the user can > >>> transition from _SAVING|_RUNNING to _SAVING at any point, regardless of > >>> pending_bytes. This should be noted. > >>> > >> > >> Ok. Updating comment. > >> > >>>> + * > >>>> + * Sequence to be followed while _RESUMING device state: > >>>> + * While data for this device is available, repeat below steps: > >>>> + * a. read data_offset from where user application should write data. > >>>> + * b. write data of data_size to migration region from data_offset. > >>> > >>> Whose's data_size, the _SAVING end or the _RESUMING end? I think this > >>> is intended to be the transaction size from the _SAVING source, > >> > >> Not necessarily. data_size could be MIN(transaction size of source, > >> migration data section). If migration data section is smaller than data > >> packet size at source, then it has to be broken and iteratively sent. > > > > So you're saying that a transaction from the source is divisible by the > > user under certain conditions. What other conditions exist? > > I don't think there are any other conditions than above. > > > Can the > > user decide arbitrary sizes less than the MIN() stated above? This > > needs to be specified. > > > > No, User can't decide arbitrary sizes. TBH, I'd expect a vendor driver that offers a different migration region size, such that it becomes the user's responsibility to split transactions should just claim it's not compatible with the source, as determined by the previously defined compatibility protocol. If we really need this requirement, it needs to be justified and the exact conditions under which the user performs this needs to be specified. > >>> but it > >>> could easily be misinterpreted as reading data_size on the _RESUMING > >>> end. > >>> > >>>> + * c. write data_size which indicates vendor driver that data is written in > >>>> + * staging buffer. Vendor driver should read this data from migration > >>>> + * region and resume device's state. > >>> > >>> I think we also need to define the error protocol. The user could > >>> mis-order transactions or there could be an internal error in the > >>> vendor driver or device. Are all read(2)/write(2) operations > >>> susceptible to defined errnos to signal this? > >> > >> Yes. > > > > And those defined errnos are specified... > > > > Those could be standard errors like -EINVAL, ENOMEM.... I thought we might specify specific errors to consistently indicate non-continuable faults among vendor drivers. Is anything other than -EAGAIN considered non-fatal to the operation? For example, could EEXIST indicate duplicate data that the user has already written but not be considered a fatal error? Would EFAULT perhaps indicate a continuable ordering error? If any fault indicates the save/resume has failed, shouldn't the user be able to see the device is in such a state by reading device_state (except we have no state defined to indicate that)? > >>> Is it reflected in > >>> device_state? > >> > >> No. > > > > So a user should do what, just keep trying? > > > > No, fail migration process. If error is at source or destination then > user can decide either resume at source or terminate application. This is describing the expected QEMU protocol resolution, the question is relative to the vfio API we're defining here. If any fault in the save/resume protocol results in the device being unusable, there should be an indication (perhaps through device_state) that the device is in a broken state, and the mechanism to put it into a new state should be defined. For instance, if the device is resuming, a fault occurs writing state data to the device, and the user transitions to running. Is the device incorporating the partial state data into its run state? I suspect not, and wouldn't that be more obvious if we defined a protocol where the device can be inspected to be in a bogus state via reading device_state, at which point we might define performing a device reset as the only mechanism to change the device_state after that point. > >>> What's the recovery protocol? > >>> > >> > >> On read()/write() failure user should take necessary action. > > > > Where is that necessary action defined? Can they just try again? Do > > they transition in and out of _RESUMING to try again? Do they need to > > reset the device? > > > > User application should decide what action to take on failure, right? > "vfio is not prescribing the migration semantics to userspace, it's > presenting an interface that support the user semantics." Exactly, we're not defining how QEMU handles a fault in this spec, we're defining how a user interacting with the device knows a fault has occurred, can inspect the device to determine that the device is in a broken state, and the "necessary action" to advance the device forward to a new state. > >>>> + * > >>>> + * For user application, data is opaque. User should write data in the same > >>>> + * order as received. > >>> > >>> Order and transaction size, ie. each data_size chunk is indivisible by > >>> the user. > >> > >> Transaction size can differ, but order should remain same. > > > > Under what circumstances and to what extent can transaction size > > differ? > > It depends in migration region size. > > > Is the MIN() algorithm above the absolute lower bound or just > > a suggestion? > > > > > Is the user allowed to concatenate transactions from the > > source together on the target if the region is sufficiently large? > > Yes that can be done, because data is just byte stream for user. Vendor > driver receives the byte stream and knows how to decode it. But that byte stream is opaque to the user, the vendor driver might implement it such that every transaction has a header and splitting the transaction might mean that the truncated transaction no longer fits the expected size. If we're lucky, the vendor driver's implementation might detect that. If we're not, the vendor driver might misinterpret the next packet. I think if the user is to consider all data as opaque, they must also consider every transaction as indivisible or else we're assuming something about the contents of that transaction. > > It > > seems like quite an imposition on the vendor driver to support this > > flexibility. > > > >>>> + */ > >>>> + > >>>> +struct vfio_device_migration_info { > >>>> + __u32 device_state; /* VFIO device state */ > >>>> +#define VFIO_DEVICE_STATE_STOP (1 << 0) > >>>> +#define VFIO_DEVICE_STATE_RUNNING (1 << 0) > >>> > >>> Huh? We should probably just refer to it consistently, ie. _RUNNING > >>> and !_RUNNING, otherwise we have the incongruity that setting the _STOP > >>> value is actually the opposite of the necessary logic value (_STOP = 1 > >>> is _RUNNING, _STOP = 0 is !_RUNNING). > >> > >> Ops, my mistake, forgot to update to > >> #define VFIO_DEVICE_STATE_STOP (0) > >> > >>> > >>>> +#define VFIO_DEVICE_STATE_SAVING (1 << 1) > >>>> +#define VFIO_DEVICE_STATE_RESUMING (1 << 2) > >>>> +#define VFIO_DEVICE_STATE_MASK (VFIO_DEVICE_STATE_RUNNING | \ > >>>> + VFIO_DEVICE_STATE_SAVING | \ > >>>> + VFIO_DEVICE_STATE_RESUMING) > >>>> + > >>>> +#define VFIO_DEVICE_STATE_INVALID_CASE1 (VFIO_DEVICE_STATE_SAVING | \ > >>>> + VFIO_DEVICE_STATE_RESUMING) > >>>> + > >>>> +#define VFIO_DEVICE_STATE_INVALID_CASE2 (VFIO_DEVICE_STATE_RUNNING | \ > >>>> + VFIO_DEVICE_STATE_RESUMING) > >>> > >>> Gack, we fixed these in the last iteration! > >>> > >> > >> That solution doesn't scale when new flags will be added. I still prefer > >> to define as above. > > > > I see, the argument was buried in a reply to Yan, sorry if I missed it: > > > >>>> These seem difficult to use, maybe we just need a > >>>> VFIO_DEVICE_STATE_VALID macro? > >>>> > >>>> #define VFIO_DEVICE_STATE_VALID(state) \ > >>>> (state & VFIO_DEVICE_STATE_RESUMING ? \ > >>>> (state & VFIO_DEVICE_STATE_MASK) == VFIO_DEVICE_STATE_RESUMING : 1) > >>>> > >> > >> This will not be work when use of other bits gets added in future. > >> That's the reason I preferred to add individual invalid states which > >> user should check. > > > > I would argue that what doesn't scale is having numerous CASE1, CASE2, > > CASEn conditions elsewhere in the kernel rather than have a unified, > > single macro that defines a valid state. How do you worry this will be > > a problem when new flags are added, can't we just update the macro? > > Adding macro you suggested above. Lets figure out how to solve problem > with new flags when new flags gets added. Agree, I think it's sufficient to assume we'll update the macro at that time. Thanks, Alex