Currently we loop over `htlcs_to_fail` locking `channel_state` for each
element only to call `get_htlc_inbound_temp_fail_err_and_data` with the
same inputs on each iteration. This is unnecessary, we can refactor and
call `get_htlc_inbound_temp_fail_err_and_data` outside of the loop.
Currently `fail_htlc_backwards_internal` takes ownership of its source
and reason parameters however they are not consumed so we can borrow them.
Includes refactoring to use local variables before the function call.
We create `HTLCFailReason` inline in function calls in a bunch of places
in the `channelmanager` module, we can make the code more terse with no
loss of clarity by implementing a couple of constructor methods.
See ChannelManager::forward_intercepted_htlc and
ChannelManager::get_intercept_scid for details
Co-authored-by: John Cantrell <johncantrell97@gmail.com>
Co-authored-by: Valentine Wallace <vwallace@protonmail.com>
And store the pending intercepted HTLC in pending_intercepted_htlcs
Co-authored-by: John Cantrell <johncantrell97@gmail.com>
Co-authored-by: Valentine Wallace <vwallace@protonmail.com>
No htlcs are intercepted yet, that will be added in upcoming commit(s)
Co-authored-by: John Cantrell <johncantrell97@gmail.com>
Co-authored-by: Valentine Wallace <vwallace@protonmail.com>
For Windows build only, the
`TestPersister::chain_sync_monitor_persistences` lock has a lock order
before the `ChannelManager::per_peer_state` lock. This fix ensures that
the `per_peer_state` lock isn't held before the
`TestPersister::chain_sync_monitor_persistences` lock is acquired.
As the `channel_state` lock will be removed, we prepare for that by
flipping the lock order for `pending_inbound_payments` and
`pending_outbound_payments` locks to before the `channel_state` lock.
Now that `handle_channel_resumption` can't fail, the error handling
in `post_handle_chan_restoration` is now dead code. Removing it
makes `post_handle_chan_restoration` only a single block, so here
we simply remove the macro and inline the single block into the two
places the macro was used.
There is no reason anymore for `handle_chan_restoration_locked` to
be a macro, and our long-term desire is to move away from macros as
they substantially bloat our compilation time (and binary size).
Thus, we simply remove `handle_chan_restoration_locked` here and
turn it into a function.
When we process a `channel_reestablish` message we free the HTLC
update holding cell as things may have changed while we were
disconnected. However, some time ago, to handle freeing from the
holding cell when a monitor update completes, we added a holding
cell freeing check in `get_and_clear_pending_msg_events`. This
leaves the in-`channel_reestablish` holding cell clear redundant,
as doing it immediately or is `get_and_clear_pending_msg_events` is
not a user-visible difference.
Thus, we remove the redundant code here, substantially simplifying
`handle_chan_restoration_locked` while we're at it.
As it was previously omitted, we clarify here starting from which version users can expect the `user_channel_id` to be randomized for inbound channels.
LND nodes have very broken fee estimators, causing them to suggest
feerates that don't even meet a current mempool minimum feerate
when fees go up over the course of hours. This can cause us to
reject their feerate estimates as they're not high enough, even
though their new feerate is higher than what we had already (which
is the feerate we'll use to broadcast a closing transaction). This
implies we force-close the channel and broadcast something with a
feerate lower than our counterparty was offering.
Here we simply accept such feerates as they are better than what we
had. We really should also close the channel, but only after we
get their signature on the new feerate. That should happen by
checking channel feerates every time we see a new block so is
orthogonal to this code.
Ultimately the fix is anchor outputs plus package-based relay in
Bitcoin Core, however we're still quite some ways from that, so
worth needlessly closing channels for now.
We increase the `user_channel_id` type from `u64` to `u128`. In order to
maintain backwards compatibility, we have to de-/serialize it as two
separate `u64`s in `Event` as well as in the `Channel` itself.
Previously, all inbound channels defaulted to a `user_channel_id` of 0,
which didn't allow for them being discerned on that basis. Here, we
simply randomize the identifier to fix this and enable the use of
`user_channel_id` as a true identifier for channels (assuming an equally
reasonable value is chosen for outbound channels and given upon
`create_channel()`).
After the first persistence-required `Future` wakeup, we'll always
complete additional futures instantly as we don't clear the
"need wake" bit. Instead, we need to just assume that if a future
was generated (and not immediately drop'd) that its sufficient to
notify the user.
When a user attempts to send a payment but it fails due to
idempotency key violation, they need to know that this was the
reason as they need to handle the error programmatically
differently from other errors.
Here we simply add a new `PaymentSendFailure` enum variant for
`DuplicatePayment` to allow for that.
