Re: [PATCH] tuntap: add flow control to support back pressure
From: Steven Galgano
Date: Sun Apr 13 2014 - 21:29:04 EST
On 04/13/2014 10:14 AM, Michael S. Tsirkin wrote:
>
> Steven, Brian,
>
> thanks for reporting this issue.
> Please see my comments below.
>
> On Fri, Apr 11, 2014 at 12:41:42PM -0400, Brian Adamson wrote:
>> To weigh in on the desire to have support (at least as an optional behavior) for the legacy flow control behavior, there are many existing uses of it. Many these are related to experimental purposes where the tuntap driver can be used (with a little user space code) as a surrogate for a network interface type that may not even yet exist. And in some cases these experimental purposes have had utility for actual deployment (e.g. disaster relief wireless networks where the TAP device has provided some intermediate assistance for routing or other protocols, even an underwater acoustic sensor network proposed for reef monitoring, etc where a TAP device provides a network interface and the sound card is used as a modem on an embedded system). Some of these networks have low data rates or packet loss and delays that make TCP (which provides flow control as part of its usual reliable transport for more typical networking purpose) not an ideal protocol to use and so UDP or other alterna
tives or used. To keep this short, I'll list a few use cases here I know (and was involved with the implementation of some) with some links (where I know them):
>>
>> 1) CORE network emulation tool (http://code.google.com/p/coreemu/)
>>
>> 2) EMANE network emulation tool (https://github.com/adjacentlink/emane)
>>
>> (likely other network emulation tools exist that have used tuntap as surrogates for real physical interfaces and expect the same backpressure to sockets and queues that physical interfaces provide)
>>
>> 3) I don't have a link to it but I implemented an experimental IP interface/ MAC protocol called SLIDE (serial-link internet daemon) that implemented a user-space CSMA MAC protocol where an underwater acoustic modem was connected to the serial port and TAP was used to present a virtual network interface to the IP stack. Because of the low data rates involved, the back pressure flow control to application sockets (and protocol daemons and qdiscs applied) was important.
>>
>> 4) User space implementation of Simplified Multicast Forwarding (SMF) of RFC 6621 has a "device" option that establishes TAP interfaces to perform distributed "backpressure" based flow control (and potentially routing) for MANET wireless networks. (http://www.nrl.navy.mil/itd/ncs/products/smf)
>>
>> There are probably some more, among the more esoteric wireless and other special networking communities, where host (or routing/gateway/proxy non-host), e.g. special embedded system devices based on Linux such as sensors, etc) have a first hop network attachment that is _not_ the typical Ethernet or something and may be using tuntap along with a sort of user-space "driver" to present an IP interface to the network stack. some of this stuff, especially embedded systems, tend to lag behind with respect to kernel versions and this behavior change in Linux may be yet undiscovered so far even though the change was put in a couple years ago.
>>
>> Several of these are implemented across multiple platforms, and, for example, BSD-based systems tuntap provides the same flow control behavior. Even if it was never formally documented, I think this behavior was fairly well known (at least for these sorts of experimental purposes) and used. I understand the concern that a single bad behaving flow can possibly block the flow of others unless traffic control queuing disciplines (as done for other network interfaces). For the purposes of which I'm aware, I think having this behavior as _optional_ is probably OK â If accepted, and something is implemented here, it may be a good opportunity to have it documented (and the pros and cons of its use) for the more general Linux community.
>
> Yes, a UDP socket with sufficiently deep qdisc and tun queues
> would previously get slowed down so it matches the speed of
> the interface.
>
> But IIUC this was not really designed to be a flow control measure,
> so depending on what else is in the qdisc you could easily get
> into a setup where it behaves exactly as it does now.
> For example, have several UDP sockets send data out a single
> interface.
>
> Another problem is that this depends on userspace to be
> well-behaved and consume packets in a timely manner:
> a misbehaving userspace operating a tun device can cause other
> tun devices and/or sockets to get blocked forever and prevent them
> from communicating with all destinations (not just the misbehaving one)
> as their wmem limit is exhausted.
>
> It should be possible to reproduce with an old kernel and your userspace
> drivers, too - just stop the daemon temporarily.
> I realize that your daemon normally is well-behaved, and
> simply moves all incoming packets to the backend without
> delay, but I'd like to find a solution that addresses
> this without trusting userspace to be responsive.
>
>
>
>
> At the moment, for this use-case it's possible to limit the speed of tun
> interface using a non work conserving qdisc. Make that match the speed
> of the backend device, and you get back basically the old behaviour
> without the security problem in that the rate is basically ensured
> by kernel and all packets queued are eventually consumed.
>
> Does this solve the problem for you?
>
>
I do not believe this solves the problem.
The issue is with what happens when a queue is full. When multiqueue
support was introduced, the tun went from stopping the queue to dropping
packets.
In the back pressure use case, the application code using the character
device side of the tun interface stops reading frames in order to cause
the tun queue to backup and eventually stop. This leads to tx socket
buffer backup which provides back pressure to the applications sending
traffic over the tun interface.
The determination as to when to stop reading frames or when to throttle
back from reading frames is dynamic. It can be based on many things:
congestion on the backend media, power level, data rate, etc.
And the application response to back pressure can be as simple as just
blocking on a send() or more complex like dynamically throttling data
rates or changing compression ratios to reduce overall network load so
that when congestion clears there is less of a strain on the network.
Once the tun started dropping packets instead of stopping the queue, it
removed the ability for the application controlling the tun to apply its
own queue management policy: read frames and possibly discard or stop
reading frames. That is the problem, the fixed discard policy.
I'll be posting another version of the patch that allows you to specify
the flow control behavior on a queue by queue basis. This would let the
application decide what should happen once a queue is full: discard or
netif_tx_stop_queue().
I'm not hopeful this solution will be accepted but it might be helpful
to someone else.
>> BTW, in my initial noticing this issue, it _seemed_ that even the default interface pfifo_fast priority bands were not being properly enforced for the tap interface without the old flow control behavior?. I need to do a little more "old vs new" comparison testing on this regard.
>>
>> best regards,
>>
>> Brian
>
> I think that as tun is never stopped, nothing is ever queued in qdisc.
>
>
>> On Apr 10, 2014, at 9:42 PM, Steven Galgano <sgalgano@xxxxxxxxxxxxxxxx> wrote:
>>
>>> On 04/10/2014 06:29 AM, Michael S. Tsirkin wrote:
>>>> On Wed, Apr 09, 2014 at 10:19:40PM -0400, Steven Galgano wrote:
>>>>> Add tuntap flow control support for use by back pressure routing protocols. Setting the new TUNSETIFF flag IFF_FLOW_CONTROL, will signal resources as unavailable when the tx queue limit is reached by issuing a netif_tx_stop_all_queues() rather than discarding frames. A netif_tx_wake_all_queues() is issued after reading a frame from the queue to signal resource availability.
>>>>>
>>>>> Back pressure capability was previously supported by the legacy tun default mode. This change restores that functionality, which was last present in v3.7.
>>>>>
>>>>> Reported-by: Brian Adamson <brian.adamson@xxxxxxxxxxxx>
>>>>> Tested-by: Joseph Giovatto <jgiovatto@xxxxxxxxxxxxxxxx>
>>>>> Signed-off-by: Steven Galgano <sgalgano@xxxxxxxxxxxxxxxx>
>>>>
>>>> I don't think it's a good idea.
>>>>
>>>> This trivial flow control really created more problems than it was worth.
>>>>
>>>> In particular this blocks all flows so it's trivially easy for one flow
>>>> to block and starve all others: just send a bunch of packets to loopback
>>>> destinations that get queued all over the place.
>>>>
>>>> Luckily it was never documented so we changed the default and nothing
>>>> seems to break, but we won't be so lucky if we add an explicit API.
>>>>
>>>>
>>>> One way to implement this would be with ubuf_info callback this is
>>>> already invoked in most places where a packet might get stuck for a long
>>>> time. It's still incomplete though: this will prevent head of queue
>>>> blocking literally forever, but a single bad flow can still degrade
>>>> performance significantly.
>>>>
>>>> Another alternative is to try and isolate the flows that we
>>>> can handle and throttle them.
>>>>
>>>> It's all fixable but we really need to fix the issues *before*
>>>> exposing the interface to userspace.
>>>>
>>>>
>>>>
>>>
>>> It was only after recent upgrades that we picked up a newer kernel and
>>> discovered the change to the default tun mode.
>>>
>>> The new default behavior has broken applications that depend on the
>>> legacy behavior. Although not documented, the legacy behavior was well
>>> known at least to those working in the back pressure research community.
>>> The default legacy mode was/is a valid use case although I am not sure
>>> it fits with recent multiqueue support.
>>>
>>> When back pressure protocols are running over a tun interface they
>>> require legacy flow control in order to communicate congestion detected
>>> on the physical media they are using. Multiqueues do not apply here.
>>> These protocols only use one queue, so netif_tx_stop_all_queues() is the
>>> necessary behavior.
>>>
>>> I'm not tied to the idea of IFF_FLOW_CONTROL. I was aiming for middle
>>> ground where an application controlling the tun interface can state it
>>> wants the legacy flow control behavior understanding its limitations
>>> concerning multiple queues.
>>>
>>> What if we resurrect IFF_ONE_QUEUE and use that as a mechanism to
>>> indicate legacy flow control. A tun instance initially configured with
>>> IFF_ONE_QUEUE would not be allowed to attach or detach queues with
>>> TUNSETQUEUE and any additional opens with the same device name would
>>> fail. This mode would use the
>>> netif_tx_stop_all_queues()/netif_tx_wake_all_queues() flow control
>>> mechanism.
>>>
>>> If a tun application wants the current default behavior with only a
>>> single queue, it would not set the IFF_ONE_QUEUE flag. Not setting
>>> IFF_MULTI_QUEUE would not imply IFF_ONE_QUEUE.
>>>
>>> I'd be happy to implement this change if it is an acceptable solution.
>>> This would allow multiqueue tun development to advance while still
>>> supporting use cases dependent on legacy flow control.
>>>
>>> -steve
>>>
>>>>> ---
>>>>> diff --git a/drivers/net/tun.c b/drivers/net/tun.c
>>>>> index ee328ba..268130c 100644
>>>>> --- a/drivers/net/tun.c
>>>>> +++ b/drivers/net/tun.c
>>>>> @@ -783,8 +783,19 @@ static netdev_tx_t tun_net_xmit(struct sk_buff *skb, struct net_device *dev)
>>>>> * number of queues.
>>>>> */
>>>>> if (skb_queue_len(&tfile->socket.sk->sk_receive_queue) * numqueues
>>>>> - >= dev->tx_queue_len)
>>>>> - goto drop;
>>>>> + >= dev->tx_queue_len) {
>>>>> + if (tun->flags & TUN_FLOW_CONTROL) {
>>>>> + /* Resources unavailable stop transmissions */
>>>>> + netif_tx_stop_all_queues(dev);
>>>>> +
>>>>> + /* We won't see all dropped packets individually, so
>>>>> + * over run error is more appropriate.
>>>>> + */
>>>>> + dev->stats.tx_fifo_errors++;
>>>>> + } else {
>>>>> + goto drop;
>>>>> + }
>>>>> + }
>>>>>
>>>>> if (unlikely(skb_orphan_frags(skb, GFP_ATOMIC)))
>>>>> goto drop;
>>>>> @@ -1362,6 +1373,9 @@ static ssize_t tun_do_read(struct tun_struct *tun, struct tun_file *tfile,
>>>>> continue;
>>>>> }
>>>>>
>>>>> + /* Wake in case resources previously signaled unavailable */
>>>>> + netif_tx_wake_all_queues(tun->dev);
>>>>> +
>>>>> ret = tun_put_user(tun, tfile, skb, iv, len);
>>>>> kfree_skb(skb);
>>>>> break;
>>>>> @@ -1550,6 +1564,9 @@ static int tun_flags(struct tun_struct *tun)
>>>>> if (tun->flags & TUN_PERSIST)
>>>>> flags |= IFF_PERSIST;
>>>>>
>>>>> + if (tun->flags & TUN_FLOW_CONTROL)
>>>>> + flags |= IFF_FLOW_CONTROL;
>>>>> +
>>>>> return flags;
>>>>> }
>>>>>
>>>>> @@ -1732,6 +1749,11 @@ static int tun_set_iff(struct net *net, struct file *file, struct ifreq *ifr)
>>>>> else
>>>>> tun->flags &= ~TUN_TAP_MQ;
>>>>>
>>>>> + if (ifr->ifr_flags & IFF_FLOW_CONTROL)
>>>>> + tun->flags |= TUN_FLOW_CONTROL;
>>>>> + else
>>>>> + tun->flags &= ~TUN_FLOW_CONTROL;
>>>>> +
>>>>> /* Make sure persistent devices do not get stuck in
>>>>> * xoff state.
>>>>> */
>>>>> @@ -1900,7 +1922,8 @@ static long __tun_chr_ioctl(struct file *file, unsigned int cmd,
>>>>> * This is needed because we never checked for invalid flags on
>>>>> * TUNSETIFF. */
>>>>> return put_user(IFF_TUN | IFF_TAP | IFF_NO_PI | IFF_ONE_QUEUE |
>>>>> - IFF_VNET_HDR | IFF_MULTI_QUEUE,
>>>>> + IFF_VNET_HDR | IFF_MULTI_QUEUE |
>>>>> + IFF_FLOW_CONTROL,
>>>>> (unsigned int __user*)argp);
>>>>> } else if (cmd == TUNSETQUEUE)
>>>>> return tun_set_queue(file, &ifr);
>>>>> diff --git a/include/uapi/linux/if_tun.h b/include/uapi/linux/if_tun.h
>>>>> index e9502dd..bcf2790 100644
>>>>> --- a/include/uapi/linux/if_tun.h
>>>>> +++ b/include/uapi/linux/if_tun.h
>>>>> @@ -36,6 +36,7 @@
>>>>> #define TUN_PERSIST 0x0100
>>>>> #define TUN_VNET_HDR 0x0200
>>>>> #define TUN_TAP_MQ 0x0400
>>>>> +#define TUN_FLOW_CONTROL 0x0800
>>>>>
>>>>> /* Ioctl defines */
>>>>> #define TUNSETNOCSUM _IOW('T', 200, int)
>>>>> @@ -70,6 +71,7 @@
>>>>> #define IFF_MULTI_QUEUE 0x0100
>>>>> #define IFF_ATTACH_QUEUE 0x0200
>>>>> #define IFF_DETACH_QUEUE 0x0400
>>>>> +#define IFF_FLOW_CONTROL 0x0010
>>>>> /* read-only flag */
>>>>> #define IFF_PERSIST 0x0800
>>>>> #define IFF_NOFILTER 0x1000
--
To unsubscribe from this list: send the line "unsubscribe linux-kernel" in
the body of a message to majordomo@xxxxxxxxxxxxxxx
More majordomo info at http://vger.kernel.org/majordomo-info.html
Please read the FAQ at http://www.tux.org/lkml/