Avoid initialization in dplane_ctx_intf_init() so
the compiler can warn us about using unintialized data.
Signed-off-by: Stephen Worley <sworley@nvidia.com>
Only clear protodown reason on shutdown/sweep, retain protodown
state.
This is to retain traditional and expected behavior with daemons
like vrrpd setting protodown. They expet it to be set on shutdown
and retained on bring up to prevent traffic from being dropped.
We must cleanup our reason code though to prevent us from blocking
others.
Signed-off-by: Stephen Worley <sworley@nvidia.com>
Add enums for set/unset of prodown state to handle the mainthread
knowing an update is already queued without actually marking it
as complete.
This is to make the logic confirm a bit more with other parts of the code
where we queue dplane updates and not update our internal structs until
success callback is received.
Signed-off-by: Stephen Worley <sworley@nvidia.com>
Add support for setting the protodown reason code.
829eb208e8
These patches handle all our netlink code for setting the reason.
For protodown reason we only set `frr` as the reason externally
but internally we have more descriptive reasoning available via
`show interface IFNAME`. The kernel only provides a bitwidth of 32
that all userspace programs have to share so this makes the most sense.
Since this is new functionality, it needs to be added to the dplane
pthread instead. So these patches, also move the protodown setting we
were doing before into the dplane pthread. For this, we abstract it a
bit more to make it a general interface LINK update dplane API. This
API can be expanded to support gernal link creation/updating when/if
someone ever adds that code.
We also move a more common entrypoint for evpn-mh and from zapi clients
like vrrpd. They both call common code now to set our internal flags
for protodown and protodown reason.
Also add debugging code for dumping netlink packets with
protodown/protodown_reason.
Signed-off-by: Stephen Worley <sworley@nvidia.com>
Use the dataplane to query and read interface NETCONF data;
add netconf-oriented data to the dplane context object, and
add accessors for it. Add handler for incoming update
processing.
Signed-off-by: Mark Stapp <mstapp@nvidia.com>
Currently when the kernel sends netlink messages to FRR
the buffers to receive this data is of fixed length.
The kernel, with certain configurations, will send
netlink messages that are larger than this fixed length.
This leads to situations where, on startup, zebra gets
really confused about the state of the kernel. Effectively
the current algorithm is this:
read up to buffer in size
while (data to parse)
get netlink message header, look at size
parse if you can
The problem is that there is a 32k buffer we read.
We get the first message that is say 1k in size,
subtract that 1k to 31k left to parse. We then
get the next header and notice that the length
of the message is 33k. Which is obviously larger
than what we read in. FRR has no recover mechanism
nor is there a way to know, a priori, what the maximum
size the kernel will send us.
Modify FRR to look at the kernel message and see if the
buffer is large enough, if not, make it large enough to
read in the message.
This code has to be per netlink socket because of the usage
of pthreads. So add to `struct nlsock` the buffer and current
buffer length. Growing it as necessary.
Fixes: #10404
Signed-off-by: Donald Sharp <sharpd@nvidia.com>
Store the fd that corresponds to the appropriate `struct nlsock` and pass
that around in the dplane context instead of the pointer to the nlsock.
Modify the kernel_netlink.c code to store in a hash the `struct nlsock`
with the socket fd as the key.
Why do this? The dataplane context is used to pass around the `struct nlsock`
but the zebra code has a bug where the received buffer for kernel netlink
messages from the kernel is not big enough. So we need to dynamically
grow the receive buffer per socket, instead of having a non-dynamic buffer
that we read into. By passing around the fd we can look up the `struct nlsock`
that will soon have the associated buffer and not have to worry about `const`
issues that will arise.
Signed-off-by: Donald Sharp <sharpd@nvidia.com>
The ctx->zd_is_update is being set in various
spots based upon the same value that we are
passing into dplane_ctx_ns_init. Let's just
consolidate all this into the dplane_ctx_ns_init
so that the zd_is_udpate value is set at the
same time that we increment the sequence numbers
to use.
As a note for future me's reading this. The sequence
number choosen for the seq number passed to the
kernel is that each context gets a copy of the
appropriate nlsock to use. Since it's a copy
at a point in time, we know we have a unique sequence
number value.
Signed-off-by: Donald Sharp <sharpd@nvidia.com>
In some cases, zebra may install a nexthop-group id that is
different from the id of the nhe struct attached to a
route-entry. This happens for a singleton recursive nexthop,
for example, where a route is installed with the resolving
nexthop's id.
The installed value is the most useful value - that corresponds
to information in the kernel on linux/netlink platforms that
support nhgs. Display both values if they differ in ascii
output, and include both values in the json form.
Signed-off-by: Mark Stapp <mstapp@nvidia.com>
Since f60a1188 we store a pointer to the VRF in the interface structure.
There's no need anymore to store a separate vrf_id field.
Signed-off-by: Igor Ryzhov <iryzhov@nfware.com>
The dplane_ctx_get_pbr_ipset_entry function only
failed when the caller did not pass in a valid
usable pointer. Change the code to assert on
a pointer not being passed in and remove the
bool return
Signed-off-by: Donald Sharp <sharpd@nvidia.com>
The only time this function ever failed is when
the developer does not pass in a usable pointer
to place the data in. Change it to an assert
to signify to the end developer that is what
we want and then remove all the if checks
for failure
Signed-off-by: Donald Sharp <sharpd@nvidia.com>
The function call dplane_ctx_get_pbr_ipset only
returns false when the calling function fails to
pass in a valid ipset pointer. This should
be an assertion issue since it's a programming
issue as opposed to an actual run time issue.
Change the function call parameter to not return
a bool on success/fail for a compile time decision.
Signed-off-by: Donald Sharp <sharpd@nvidia.com>
It is needed for the ipset entry to know for which address family
this ipset entry applies to. Actually, the family is in the original
ipset structure and was not passed as attribute in the dataplane
ipset_info structure. Add it.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
When injecting an ipset entry into the zebra dataplane context, the
ipset name is stored in a separate structure. This will permit the
flowspec plugin to be able to know which ipset has to be appended with
relevant ipset entry.
The problem was that the zebra dataplane objects related to ipset entries
is made up of an union between the ipset structure and the ipset info
structure. This was implying that the two structures were on the same
memory zone, and when extracting the data stored, the data were incomplete.
Fix this by replacing the union structure by a defined struct.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
Read incoming interface address change notifications in the
dplane pthread; enqueue the events to the main pthread
for processing. This is netlink-only for now - the bsd
kernel socket path remains unchanged.
Signed-off-by: Mark Stapp <mjs.ietf@gmail.com>
Add a new netlink socket for events coming in from the host OS
to the dataplane system for processing. Rename the existing
outbound dplane socket.
Signed-off-by: Mark Stapp <mjs.ietf@gmail.com>
Include the complete set of primary and backup nexthops from
the resolving route for a pseudowire. Add accessors for that
info. Modify the logic that creates the fib set of pw nexthops
so that only installed, labelled nexthops are included.
Signed-off-by: Mark Stapp <mjs@voltanet.io>
- gre keys are collected and stored locally.
- when gre source set is requested, and the link interface
configured is different, the gre information collected is
pushed in the query, namely source ip or gre keys if present.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
preserve mtu upon interface flapping and tunnel source change.
Signed-off-by:Reuben Dowle <reuben.dowle@4rf.com>
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
This action is initiated by nhrp and has been stubbed when
moving to zebra. Now, a netlink request is forged to set
the link interface of a gre interface if that gre interface
does not have already a link interface.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
do not add a new route type, and consider 0 as a value meaning
that zebra should be the owner.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
zapi_nbr structure is renamed to zapi_neigh_ip.
Initially used to set a neighbor ip entry for gre interfaces, this
structure is used to get events from the zebra layer to nhrp layer.
The ndm state has been added, as it is needed on both sides.
The zebra dplane layer is slightly modified.
Also, to clarify what ZEBRA_NEIGH_ADD/DEL means, a rename is done:
it is called now ZEBRA_NEIGH_IP_ADD/DEL, and it signified that this
zapi interface permits to set link operations by associating ip
addresses to link addresses.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
Instead of directly configuring the neighbor table after read from zapi
interface, a zebra dplane context is prepared to host the interface and
the family where the neighbor table is updated. Also, some other fields
are hosted: app_probes, ucast_probes, and mcast_probes. More information
on those fields can be found on ip-ntable configuration.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
EVPN neighbor operations were already done in the zebra dataplane
framework. Now that NHRP is able to use zebra to perform neighbor IP
operations (by programming link IP operations), handle this operation
under dataplane framework:
- assign two new operations NEIGH_IP_INSTALL and NEIGH_IP_DELETE; this
is reserved for GRE like interfaces:
example: ip neigh add A.B.C.D lladdr E.F.G.H
- use 'struct ipaddr' to store and encode the link ip address
- reuse dplane_neigh_info, and create an union with mac address
- reuse the protocol type and use it for neighbor operations; this
permits to store the daemon originating this neighbor operation.
a new route type is created: ZEBRA_ROUTE_NEIGH.
- the netlink level functions will handle a pointer, and a type; the
type indicates the family of the pointer: AF_INET or AF_INET6 if the
link type is an ip address, mac address otherwise.
- to keep backward compatibility with old queries, as no extension was
done, an option NEIGH_NO_EXTENSION has been put in place
- also, 2 new state flags are used: NUD_PERMANENT and NUD_FAILED.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
This one also needed a bit of shuffling around, but MTYPE_RE is the only
one left used across file boundaries now.
Signed-off-by: David Lamparter <equinox@diac24.net>
Back when I put this together in 2015, ISO C11 was still reasonably new
and we couldn't require it just yet. Without ISO C11, there is no
"good" way (only bad hacks) to require a semicolon after a macro that
ends with a function definition. And if you added one anyway, you'd get
"spurious semicolon" warnings on some compilers...
With C11, `_Static_assert()` at the end of a macro will make it so that
the semicolon is properly required, consumed, and not warned about.
Consistently requiring semicolons after "file-level" macros matches
Linux kernel coding style and helps some editors against mis-syntax'ing
these macros.
Signed-off-by: David Lamparter <equinox@diac24.net>
like it has been done for iptable contexts, a zebra dplane context is
created for each ipset/ipset entry event. The zebra_dplane_ctx job is
then enqueued and processed by separate thread. Like it has been done
for zebra_pbr_iptable context, the ipset and ipset entry contexts are
encapsulated into an union of structures in zebra_dplane_ctx.
There is a specificity in that when storing ipset_entry structure, there
was a backpointer pointer to the ipset structure that is necessary
to get some complementary information before calling the hook. The
proposal is to use an ipset_entry_info structure next to the ipset_entry,
in the zebra_dplane context. That information is used for ipset_entry
processing. The ipset name and the ipset type are the only fields
necessary.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
The iptable processing was not handled in remote dataplane, and was
directly processed by the thread in charge of zapi calls. Now that call
can be handled in the zebra_dplane separate thread. once a
zebra_dplane_ctx is allocated for iptable handling, the hook call is
performed later. Subsequently, a return code may be triggered to zclient
interface if any problem occurs when calling the hook call.
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
Feature overview:
=================
A 802.3ad bond can be setup to allow lacp-bypass. This is done to enable
servers to pxe boot without a LACP license i.e. allows the bond to go oper
up (with a single link) without LACP converging.
If an ES-bond is oper-up in an "LACP-bypass" state MH treats it as a non-ES
bond. This involves the following special handling -
1. If the bond is in a bypass-state the associated ES is placed in a
bypass state.
2. If an ES is in a bypass state -
a. DF election is disabled (i.e. assumed DF)
b. SPH filter is not installed.
3. MACs learnt via the host bond are advertised with a zero ESI.
When the ES moves out of "bypass" the MACs are moved from a zero-ESI to
the correct non-zero id. This is treated as a local station move.
Implementation:
===============
When (a) an ES is detached from a hostbond or (b) an ES-bond goes into
LACP bypass zebra deletes all the local macs (with that ES as destination)
in the kernel and its local db. BGP re-sends any imported MAC-IP routes
that may exist with this ES destination as remote routes i.e. zebra can
end up programming a MAC that was perviously local as remote pointing
to a VTEP-ECMP group.
When an ES is attached to a hostbond or an ES-bond goes
LACP-up (out of bypss) zebra again deletes all the local macs in the
kernel and its local db. At this point BGP resends any imported MAC-IP
routes that may exist with this ES destination as sync routes i.e.
zebra can end up programming a MAC that was perviously remote
as local pointing to an access port.
Signed-off-by: Anuradha Karuppiah <anuradhak@cumulusnetworks.com>
