This makes it easier for our automated bindings generator to
function as it tries to automatically create a ::new if the struct
contains only pub elements who's type is convertible.
This caused a bunch of cascading changes, including
passing loggers down to Channels in function calls
rather than having each Channel have a pointer to the
ChannelManager's Logger (which was a circular reference).
Other structs that the Channel had passed its Logger to also
had their loggers removed. Other newly unused Loggers were
also removed, especially when keeping them would've caused
a bunch of extra test changes to be necessary, e.g. with
the ChainWatchInterfaceUtil's Logger.
This simplifies channelmonitor quite nicely (as expected) as we
never have to be concerned with learning data in a DataLossProtect
which is require for us to claim our funds from the latest remote
commitment transaction.
ChannelManager::send_payment stopped utilizing its ownership of the
Route with MPP (which, for readability, now clone()s the individual
paths when creating HTLCSource::OutboundRoute objects). While this
isn't ideal, it likely also makes sense to ensure that the user has
access to the Route after sending to correlate individual path
failures with the paths in the route or, in the future, retry
individual paths.
Thus, the easiest solution is to just take the Route by reference,
allowing the user to retain ownership.
Base AMP is centered around the concept of a 'payment_secret` - an
opaque 32-byte random string which is used to authenticate the
sender to the recipient as well as tie the various HTLCs which
make up one payment together. This new field gets exposed in a
number of places, though sadly only as an Option for backwards
compatibility when sending to a receiver/receiving from a sender
which does not support Base AMP.
Sadly a huge diff here, but almost all of it is changing the method
signatures for sending/receiving/failing HTLCs and the
PaymentReceived event, which all now need to expose an
Option<[u8; 32]> for the payment_secret.
It doesn't yet properly fail back pending HTLCs when the full AMP
payment is never received (which should result in accidental
channel force-closures). Further, as sending AMP payments is not
yet supported, the only test here is a simple single-path payment
with a payment_secret in it.
The way PeerHandler was written, it was supposed to remove from
self.peers iff the API docs indicate that disconnect_event should
NOT be called (and otherwise rely on disconnect_event to do so).
Sadly, the implementation was way out of whack with reality - in
the implementation, essentially anywhere where PeerHandler
originated the disconnection, the peer was removed and no
disconnect_event was expected. The docs, however, indicated that
disconnect_event should nearly only be called, only not doing so
when the initial handshake message never completed.
We opt to change the docs, mostly, as well as clean up the
ping/pong handling somewhat and rename a few functions to clarify
what they actually do.
Additional changes:
* Update fuzz crate to match ChannelManager's new API
* Update lightning-net-tokio library to match ChannelManager's new ChannelMonitor Deref API
* Update tests to match ChannelManager's new ChannelMonitor Deref API
full_stack_target found a crash where we may overflow ruring fee
calculation if a transaction appears on-chain with massive value
available for us to claim. Since these transactions are clearly
bogus, we shouldn't allow full_stack_target to connect them, but
we also improve the error generated by explicitly panicing on them.
Previously, in each of our fuzz tests we had a dummy test which
had a hard-coded hex string which it passed into the fuzz target
so that when a failing test case was found, its hex could be
copied into the test and you could run cargo test to analyze the
failure. However, this was somewhat unwieldy as converting large
tests back and forth between hex and raw files is quite annoying.
Instead, we replace each of those tests with a test in each target
that looks for files in fuzz/test_cases and runs each file it finds.
Since we're editing every bin target anyway, we also automate adding
no_main to libfuzzer builds with #![cfg_attr].
Instead of having in-memory access to the list of private keys
associated with a channel, we should have a generic API which
allows us to request signing, allowing the user to store private
keys any way they like.
The first step is the (rather mechanical) process of templating
the entire tree of ChannelManager -> Channel impls by the
key-providing type. In a later commit we should expose only public
keys where possible.
