On 08/23/2014 07:51 AM, Thomas Graf wrote:
On 08/23/14 at 11:24am, Jiri Pirko wrote:
Sat, Aug 23, 2014 at 12:53:34AM CEST, sfel...@cumulusnetworks.com wrote:
On Aug 22, 2014, at 12:39 PM, John Fastabend <john.fastab...@gmail.com> wrote:
- this requires OVS to be loaded to work. If all I want is
direct access to the hardware flow tables requiring openvswitch.ko
shouldn't be needed IMO. For example I may want to use the
hardware flow tables with something not openvswitch and we
shouldn't preclude that.
The intent is to use openvswitch.ko’s struct sw_flow to program hardware via
the ndo_swdev_flow_* ops, but otherwise be independent of OVS. So the upper
layer of the driver is struct sw_flow and any module above the driver can
construct a struct sw_flow and push it down via ndo_swdev_flow_*. So your
non-OVS use-case should be handled. OVS is another use-case. struct sw_flow
should not be OVS-aware, but rather a generic flow match/action sufficient to
offload the data plane to HW.
Yes. I was thinking about simple Netlink API that would expose direct
sw_flow manipulation (ndo_swdev_flow_* wrapper) to userspace. I will
think abou that more and perhaps add it to my next patchset version.
I agree that this might help to give a better API consumption example
for everyone not familiar with OVS.
Yep and it solves one of my simple cases where I have macvlan configured
with SR-IOV or the l2-dfwd-offload bit set and want to push some basic
static ACLs into the flow table. If you have to bring the port into the
OVS framework I'm not sure how make this coexist.
- Also there is no programmatic way to learn which flows are
in hardware and which in software. There is a pr_warn but
that doesn't help when interacting with the hardware remotely.
I need some mechanism to dump the set of hardware tables and
the set of software tables.
Agreed, we need a way to annotate which flows are installed hardware.
Yes, we discussed that already. We need to make OVS daemon hw-offload
aware indicating which flow it want/prefers to be offloaded. This is I
believe easily extentable feature and can be added whenever the right
time is.
I think the swdev flow API is good as-is. The bitmask specyfing the
offload preference with all the granularity (offload-or-fail,
try-to-offload, never-offload) needed can be added later, either in
OVS only or in swdev itself.
What is unclear in this patch is how OVS user space can know which
flows are offloaded and which aren't. A status field would help here
which indicates either: flow inserted and offloaded, flow inserted but
not offloaded. Given that, the API consumer can easily keep track of
which flows are currently offloaded.
Right. I think this is basically what Jiri and I discussed when he
originally posted the series. For my use cases this is one of the
more interesting pieces. If no one else is looking at it I can try
it on some of the already existing open source drivers that have some
very simple support for ingress flow tables read flow director.
Also, I'm not sure whether flow expiration is something the API must
take care of. The current proposal assumes that HW flows are only
ever removed by the API itself. Could the switch CPU run code which
removes flows as well? That would call for Netlink notifications.
Not that it's needed at this stage of the code but maybe worth
considerating for the API design.
I think this will be very useful when we get to a point where we
can use this on some of the switch silicon that supports bigger tables
with more capabilities. Like you say we probably don't need it in
the first draft but having a path to support it is needed.
- Simply duplicating the software flow/action into
hardware may not optimally use the hardware tables. If I have
a TCAM in hardware for instance. (This is how I read the patch
let me know if I missed something)
The hardware-specific driver is the right place to handle optimizing the
flow/action in hardware since only the driver can know the size/shape of the
device. struct sw_flow is a generic flow description; how (or if) a flow gets
programmed into hardware must be handled in the swdev driver. If the device
driver can’t make the sw_flow fit into HW because of resource limitations or
the flow simply can’t be represented in HW, then the flow is SW only.
In the rocker driver posted in this patch set, the steps are to parse the
struct sw_flow to figure out what type of flow match/action we’re dealing with
(L2 or L3 or L4, ucast or mcast, ipv4 or ipv6, etc) and then install the
correct entries into the corresponding device tables within the constraints of
the device’s pipeline. Any optimizations, like coalescing HW entries, is
something only the driver can do.
The later examples definitely make sense and I'm not argueing against
that. There is also a non hardware capabilities perspective that I
would like to present:
1) TCAM capacity is limtied, we offload based on some priority assigned
to flows. Some are critical and need to be in HW, others are best effort,
others never go into hardware. An API user will likely want to offload
best-effort flows until some watermark is reached and then switch to
critical flows only. The driver is not the right place for high level
optimization like this. The kernel API might but doesn't really have to
either because it would mean we need APIs to transfer all of the
needed context for the decision in the kernel. It might be easier to
expose the hardware context to user space instead and handle these
kind of optimizations in something like Quagga.
2) There is definitely a desire to allow adapting the software flow table
based on the hardware capabilities. Example, given a route like this:
20.1.0.0/16, mark=50, tos=0x12, actions: output:eth1
The hardware can satisfy everything except the mark=50 match. Given a
a blind 1:1 copy between hardware and software we cannot offload
because a mach would be illegal. With the full context as available
north of the API, this could be translated into something like this:
HW: 20.1.0.0/16, tos=0x12, actions: meta=1, output:cpu
SW: meta=1, mark=50, output:eth1
This will allow for partial offloads to bypass expensive masked flow
table lookups by converting them into efficient flat exact match
tables, offload TC classifiers, nftables or even the existing L2 and
L3 forwarding path.
Thanks. This is exactly what I was trying to hint at and why the
optimization can not be done in the driver. The driver shouldn't
have to know about the cost models of SW vs HW rules or how to
break up rules into sets of complimentary hw/sw rules.
the other thing I've been thinking about is how to handle hardware
with multiple flow tables. We could let the driver handle this
but if I ever want to employ a new optimization strategy then I
need to rewrite the driver. To me this looks a lot like policy
which should not be driven by the kernel. We can probably ignore
this case for the moment until we get some of the other things
addressed.
In summary, I think the swdev API as proposed is a good start as the
in-kernel flow abstraction is sufficient for many API users but we
should consider enabling the model described above as well once we
have the basic model put in place. I will be very interested in helping
out on this for both existing classifiers and OVS flow tables.
- I need a way to specify put this flow/action in hardware,
put this flow/action in software, or put this in both software
and hardware.
This seems above the swdev layer. In other words, don’t call ndo_swdev_flow_*
if you don’t want flow match/action install in HW.
It can certainly be done northbound but this seems like a basic
requirement and we might end up avoiding the code duplication and
extending the API instead.
IMO I think extending the API is the easiest route but the best
way to resolve this is to try and write the code. I'll take a
stab at it next week.
by the way Jiri I think the patches are a great start.
Thanks,
John
--
John Fastabend Intel Corporation
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