On 2017年09月10日 13:06, Michael S. Tsirkin wrote:
This is an update from v2 version. Changes: - update event suppression mechanism - add wrap counter: DESC_WRAP flag in addition to DESC_DRIVER flag used for validity so device does not have to write out all used descriptors.
Do we have benchmark result to show the advantage of DESC_DRIVER over e.g avail/used index?
- more options especially helpful for hardware implementations - in-order processing option due to popular demand - list of TODO items to consider as a follow-up, only two are open questions we need to descide now, marked as blocker, others are future enhancement ideas. --- Performance analysis of this is in my kvm forum 2016 presentation. The idea is to have a r/w descriptor in a ring structure, replacing the used and available ring, index and descriptor buffer. Note: the following mode of operation will actually work without changes when descriptor rings do not overlap, with driver writing out available entries in a read-only driver descriptor ring, device writing used entries in a write-only device descriptor ring. TODO: does this have any value for some? E.g. as a security feature? * Descriptor ring: Driver writes descriptors with unique index values and DESC_DRIVER set in flags.
You probably mean DESC_HW here?
Descriptors are written in a ring order: from start to end of ring, wrapping around to the beginning. Device writes used descriptors with correct len, index, and DESC_HW clear. Again descriptors are written in ring order. This might not be the same order of driver descriptors, and not all descriptors have to be written out. Driver and device are expected to maintain (internally) a wrap-around bit, starting at 0 and changing value each time they start writing out descriptors at the beginning of the ring. This bit is passed as DESC_WRAP bit in the flags field.
I'm not sure this is really needed, I think it could be done through checking vq.num?
Flags are always set/cleared last. Note that driver can write descriptors out in any order, but device will not execute descriptor X+1 until descriptor X has been read as valid. Driver operation: Driver makes descriptors available to device by writing out descriptors in the descriptor ring. Once ring is full, driver waits for device to use some descriptors before making more available. Descriptors can be used by device in any order, but must be read from ring in-order, and must be read completely before starting use. Thus, once a descriptor is used, driver can over-write both this descriptor and any descriptors which preceded it in the ring. Driver can detect use of descriptor either by device specific means (e.g. detect a buffer data change by device) or in a generic way by detecting that a used buffer has been written out by device. Driver writes out available scatter/gather descriptor entries in guest descriptor format: #define DESC_WRAP 0x0040 #define DESC_DRIVER 0x0080 struct desc { __le64 addr; __le32 len; __le16 index; __le16 flags; }; Fields: addr - physical address of a s/g entry len - length of an entry index - unique index. The low $\lceil log(N) \rceil - 1$ bits of the index is a driver-supplied value which can have any value (under driver control). The high bits are reserved and should be set to 0.
Drivers usually have their own information ring, so I'm not sure exposing such flexibility is really needed. For completion the only hardware meaningful information is the index of the descriptor. And DESC_WRAP could be checked implicitly through index in desc < index of this descriptor. (Though I'm still not quite sure DESC_WRAP is needed).
flags - descriptor flags. Descriptors written by driver have DESC_DRIVER set. Writing out this field makes the descriptor available for the device to use, so all other fields must be valid when it is written. DESC_WRAP - device uses this field to detect descriptor change by driver.
This looks a little bit confused, device in fact can check this through DESC_HW (or DESC_DRIVER) too?
Driver can use 1 bit to set direction /* This marks a descriptor as write-only (otherwise read-only). */ #define VRING_DESC_F_WRITE 2 Device operation (using descriptors): Device is looking for descriptors in ring order. After detecting that the flags value has changed with DESC_DRIVER set and DESC_WRAP matching the wrap-around counter, it can start using the descriptors. Descriptors can be used in any order, but must be read from ring in-order. In other words device must not read descriptor X after it started using descriptor X+1. Further, all buffer descriptors must be read completely before device starts using the buffer. This because once a descriptor is used, driver can over-write both this descriptor and any preceeding descriptors in ring. To help driver detect use of descriptors and to pass extra meta-data to driver, device writes out used entries in device descriptor format: #define DESC_WRAP 0x0040 #define DESC_DRIVER 0x0080 struct desc { __le64 reserved; __le32 len; __le16 index; __le16 flags; }; Fields: reserved - can be any value, ignored by driver len - length written by device. only valid if VRING_DESC_F_WRITE is set len bytes of data from beginning of buffer are assumed to have been updated index - unique index copied from the driver descriptor that has been used. flags - descriptor flags. Descriptors written by device have DESC_DRIVER clear. Writing out this field notifies the driver that it can re-use the descriptor id. It is also a signal that driver can over-write the relevant descriptor (with the supplied id), and any other DESC_WRAP - driver uses this field to detect descriptor change by device. If device has used a buffer containing a write descriptor, it sets this bit: #define VRING_DESC_F_WRITE 2 * Driver scatter/gather support Driver can use 1 bit to chain s/g entries in a request, similar to virtio 1.0: /* This marks a buffer as continuing in the next ring entry. */ #define VRING_DESC_F_NEXT 1 When driver descriptors are chained in this way, multiple descriptors are treated as a part of a single transaction containing an optional write buffer followed by an optional read buffer. All descriptors in the chain must have the same ID. Unlike virtio 1.0, use of this flag will be an optional feature so both devices and drivers can opt out of it. If they do, they can either negotiate indirect descriptors or use single-descriptor entries exclusively for buffers. Device might detect a partial descriptor chain (VRING_DESC_F_NEXT set but next descriptor not valid). In that case it must not use any parts of the chain - it will later be completed by driver, but device is allowed to store the valid parts of the chain as driver is not allowed to change them anymore.
Does it mean e.g device need to busy wait for complete chain if it found an incomplete one? Looks suboptimal.
Two options are available: Device can write out the same number of descriptors for the chain, setting VRING_DESC_F_NEXT for all but the last descriptor. Driver will ignore all used descriptors with VRING_DESC_F_NEXT bit set. Device only writes out a single descriptor for the whole chain. However, to keep device and driver in sync, it then skips a number of descriptors corresponding to the length of the chain before writing out the next used descriptor. After detecting a used descriptor driver must find out the length of the chain that it built in order to know where to look for the next device descriptor. * Indirect buffers Indirect buffer descriptors is an optional feature. These are always written by driver, not the device. Indirect buffers have a special flag bit set - like in virtio 1.0: /* This means the buffer contains a table of buffer descriptors. */ #define VRING_DESC_F_INDIRECT 4 VRING_DESC_F_WRITE and VRING_DESC_F_NEXT are always clear. len specifies the length of the indirect descriptor buffer in bytes and must be a multiple of 16. Unlike virtio 1.0, the buffer pointed to is a table, not a list: struct indirect_descriptor_table { /* The actual descriptors (16 bytes each) */ struct indirect_desc desc[len / 16]; }; The first descriptor is located at start of the indirect descriptor table, additional indirect descriptors come immediately afterwards. struct indirect_desc { __le64 addr; __le32 len; __le16 reserved; __le16 flags; }; DESC_F_WRITE is the only valid flag for descriptors in the indirect table. Others should be set to 0 and are ignored. reserved field is also set to 0 and should be ignored. TODO (blocker): virtio 1.0 allows a s/g entry followed by an indirect descriptor. Is this useful? This support would be an optional feature, same as in virtio 1.0 * Batching descriptors: virtio 1.0 allows passing a batch of descriptors in both directions, by incrementing the used/avail index by values > 1. At the moment only batching of used descriptors is used. We can support this by chaining a list of device descriptors through VRING_DESC_F_MORE flag. Device sets this bit to signal driver that this is part of a batch of used descriptors which are all part of a single transaction.
If this is a part of a single transaction, I don't see obvious different with DESC_F_NEXT?). I thought for batching, each descriptor is independent and should belong to several different transactions. (E.g for net, each descriptor could be an independent packet).
Driver might detect a partial descriptor chain (VRING_DESC_F_MORE set but next descriptor not valid). In that case it must not use any parts of the chain - it will later be completed by device, but driver is allowed to store the valid parts of the chain as device is not allowed to change them anymore. Descriptor should not have both VRING_DESC_F_MORE and VRING_DESC_F_NEXT set. * Using descriptors in order Some devices can guarantee that descriptors are used in the order in which they were made available. This allows driver optimizations and can be negotiated through a feature bit. * Per ring flags It is useful to support features for some rings but not others. E.g. it's reasonable to use single buffers for RX rings but sg or indirect for TX rings of the network device. Generic configuration space will be extended so features can be negotiated per ring. * Selective use of descriptors As described above, descriptors with NEXT bit set are part of a scatter/gather chain and so do not have to cause device to write a used descriptor out. Similarly, driver can set a flag VRING_DESC_F_MORE in the descriptor to signal to device that it does not have to write out the used descriptor as it is part of a batch of descriptors. Device has two options (similar to VRING_DESC_F_NEXT): Device can write out the same number of descriptors for the batch, setting VRING_DESC_F_MORE for all but the last descriptor. Driver will ignore all used descriptors with VRING_DESC_F_MORE bit set. Device only writes out a single descriptor for the whole batch. However, to keep device and driver in sync, it then skips a number of descriptors corresponding to the length of the batch before writing out the next used descriptor. After detecting a used descriptor driver must find out the length of the batch that it built in order to know where to look for the next device descriptor.
A silly question, how can driver find out the length of the batch effectively? Looks like it can only scan the ring until one that has DESC_HW cleared?
TODO (blocker): skipping descriptors for selective and scatter/gather seem to be only requested with in-order right now. Let's require in-order for this skipping? This will simplify the accounting by driver. * Interrupt/event suppression virtio 1.0 has two mechanisms for suppression but only one can be used at a time. we pack them together in a structure - one for interrupts, one for notifications: struct event { __le16 idx; __le16 flags; } Both fields would be optional, with a feature bit: VIRTIO_F_EVENT_IDX VIRTIO_F_EVENT_FLAGS Flags can be used like in virtio 1.0, by storing a special value there: #define VRING_F_EVENT_ENABLE 0x0 #define VRING_F_EVENT_DISABLE 0x1 Event index includes the index of the descriptor which should trigger the event, and the wrap counter in the high bit.
Not specific to v3, but looks like with event index, we can't achieve interruptless or exitless consider idx may wrap.
In that case, interrupt triggers when descriptor is written at a given location in the ring (or skipped in case of NEXT/MORE). If both features are negotiated, a special flags value can be used to switch to event idx: #define VRING_F_EVENT_IDX 0x2 * Available notification Driver currently writes out the queue number to device to kick off ring processing. As queue number is currently 16 bit, we can extend that to additionally include the offset within ring of the descriptor which triggered the kick event in bits 16 to 30, and the wrap counter in the high bit (31). Device is allowed to pre-fetch descriptors beyond the specified offset but is not required to do so.
With DESC_HW or other flag, prefetching may introduce extra overhead I think since it need to keep scan descriptor until DESC_HW is not set?
* TODO: interrupt coalescing Does it make sense just for networking or for all devices? If later should we make it a per ring or a global feature? * TODO: event index/flags in device memory? Should we move the event index/flags to device memory? Might be helpful for hardware configuration so they do not need to do DMA reads to check whether interrupt is needed. OTOH maybe interrupt coalescing is sufficient for this. * TODO: Device specific descriptor flags We have a lot of unused space in the descriptor. This can be put to good use by reserving some flag bits for device use. For example, network device can set a bit to request that header in the descriptor is suppressed (in case it's all 0s anyway). This reduces cache utilization. Note: this feature can be supported in virtio 1.0 as well, as we have unused bits in both descriptor and used ring there.
I think we need try at least packing virtio-net header in the descriptor ring.
* TODO: Descriptor length in device descriptors Some devices use identically-sized buffers in all descriptors. Ignoring length for driver descriptors there could be an option too. * TODO: Writing at an offset Some devices might want to write into some descriptors at an offset, the offset would be in reserved field in the descriptor, possibly a descriptor flag could indicate this: #define VRING_DESC_F_OFFSET 0x0020 How exactly to use the offset would be device specific, for example it can be used to align beginning of packet in the 1st buffer for mergeable buffers to cache line boundary while also aligning rest of buffers.
May be even more e.g NET_SKB_PAD, then we could use build_skb() for Linux drivers.
* TODO: Non power-of-2 ring sizes As the ring simply wraps around, there's no reason to require ring size to be power of two. It can be made a separate feature though. TODO: limits on buffer alignment/size Seems to be useful for RX for networking. Is there a need to negotiate above in a generic way or is this a networking specific optimization? TODO: expose wrap counters to device for debugging TODO: expose last avail/used offsets to device/driver for debugging TODO: ability to reset individual rings
Any actual usage of this? Thanks
--- Note: should this proposal be accepted and approved, one or more claims disclosed to the TC admin and listed on the Virtio TC IPR page https://www.oasis-open.org/committees/virtio/ipr.php might become Essential Claims. Note: the page above is unfortunately out of date and out of my hands. I'm in the process of updating ipr disclosures in github instead. Will make sure all is in place before this proposal is put to vote. As usual this TC operates under the Non-Assertion Mode of the OASIS IPR Policy, which protects anyone implementing the virtio spec.
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