Right now 'ipv6_addr_split_iface' assumes that the interface specifier
will always be a number (based on GNRC way of identifying interfaces),
but this may not be always the case.In order to be able to use the
Network Interface API, interfaces should be referred by their name.
This changes 'ipv6_addr_split_iface' so it returns a pointer to the
string that specifies the interface.
45f7966 made the `src_len` field the "emptiness signifier" for the VRB.
However, when `gnrc_sixlowpan_frag` is compiled in, the remove function
`gnrc_sixlowpan_frag_vrb_rm()` does not set the `src_len` to zero,
resulting in already deleted entry to be recognized as non-empty.
This allows to set a timer between the completion of a datagram in the
reassembly buffer and the deletion of the corresponding reassembly
buffer entry. This allows to ignore potentially late incoming link-layer
duplicates of fragments of the datagram that then will have the
reassembly buffer entry be blocked.
This was noted in this [discussion] for classic 6LoWPAN reassembly (and
minimal fragment forwarding) and is recommended in the current
[selective fragment recovery draft][SFR draft].
[discussion]: https://mailarchive.ietf.org/arch/msg/6lo/Ez0tzZDqawVn6AFhYzAFWUOtJns
[SFR draft]: https://tools.ietf.org/html/draft-ietf-6lo-fragment-recovery-07#section-6
As analyzed in #12678 there are cases where different reports can be
generated for the different snips of the packet send via the `sock`.
To catch all errors generated by the stack, the sock has to subscribe
for all snips of the packet sent. If any of the snips reports an error
distinct from `GNRC_NETERR_SUCCESS` or the previous one, we report that
status instead of just the first we receive. This way we are ensured to
have the first error reported by the stack for the given packet.
cd1ce6b98d accidentally disabled generating documentation for
`xtimer_msg_*()` functions.
Always define those functions when building the documentation.
Arduino is always enabling C++11 support, so sketches and libs are depending on
it. Every C++ compiler has been enabling C++11 by default for some years now.
Still, Ubuntu's avr-gcc is so **horrible** out of date, that it is not enabled
there. As a simple work around, -std=c++11 is now passed to the C++ compiler if
Arduino is used.
This imports the protocol parameters for Selective Fragment Recovery
(SFR). For the values I took some educated guesses based on my
experience with previous experimentation with fragment forwarding.
The defines currently are based on [draft v7].
[draft v7]: https://tools.ietf.org/html/draft-ietf-6lo-fragment-recovery-07#section-7.1
fixup! gnrc_sixlowpan_frag: initial import of SRF parameters
The name `fragment_msg` or `frag_msg`/`msg_frag` always to me was a bit
misplaced, as it basically implements an asynchronous fragmentation
buffer and doesn't necessarily have anything to do with messages.
This change
1. changes the name to `fb` (for fragmentation buffer)
2. factors its code out to its own sub-module so it can be re-used by
other 6LoWPAN fragmentation schemes like [Selective Fragment
Recovery]
[Selective Fragment Recovery]: https://tools.ietf.org/html/draft-ietf-6lo-fragment-recovery-05
The interface is already fetched in the beginning of the function and
doesn't change during its run, so getting the interface again at this
point is just redundant.
When decoding IPHC in a fragmented datagram, relying on the size of the
allocated space for the decoded packet is wrong when fragments are
forwarded and decoded on an intermediate node (for which the reassembly
buffer's space is used): Using the full datagram size for allocation in
this case would be wasteful, so the allocated space is only marginally
larger than the fragment's compressed form.
This in turn results in the wrong UDP payload size being chosen and
even worse being forwarded to the subsequent nodes.
This change uses the (virtual) reassembly buffer's `datagram_size`
instead of relying on the allocated space for the encoded
datagram/fragment.
