We create a more generic copy of the dropwtxmgr command's functionality
and export it as the DropTransactionHistory function.
It removes all transaction history from the given wallet to force a
full chain rescan. Optionally the user-defined transaction labels can be
preserved.
Because of an incorrect test, it wasn't discovered that the scriptSig
field was being set on the unsigned TX inputs for a nested SegWit input.
This commit fixes the bug and also refactors the test so it would have
caught this specific bug.
To fix a bug where specifying multiple UTXOs that are by themselves
large enough to satisfy the output amount would lead to the rest of them
being added to fees, we need to provide the transaction author with a
constant list of UTXOs. If we didn't, the author would only consider one
input and calculate the change based on that alone. But since we'd add
all inputs to the PSBT, the rest of the amounts would go to fees.
To make it easy to show the user what change output was created (if any)
during the funding process, we return its index (or -1 if no change
output was created).
In this commit, we fix a 3 year old bug in dust calculation. Before this
commit, the target fee of the transaction to be crafted would be used to
determine dust. If the target fee is very high, then this would cause
over all higher fees, as we'd base that dust computation off of that fee
rate, rather than the min relay fee.
To fix this, we always use the min relay fee at all times when computing
dust.
There's no need to retrieve the full block as we're only interesting in
retrieve its corresponding height, which can be done with
GetBlockHeaderVerbose.
All label parameter to PublishTransaction. Pass in an empty string
in rpc call as a placeholder for follow up PR which will add a label
parameter to the PublishTransaction request.
This PR allows the creation of managers and accounts that are watch-only. The state of the database after creation would be identical to the state after calling
Manager.ConvertToWatchingOnly, assuming accounts with the right xpubs were created in the former case.
Co-authored-by: Ken Sedgwick <ken@bonsai.com>
In similar fashion to the previous commit, due to a no longer existing
bug within the wallet, it was possible for change addresses to be
created outside of their intended key scope (the default), so wallets
affected by this now need to ensure upon recovery that they scan the
chain for _all_ existing key scopes, rather than just the default ones,
to reflect their proper balance. Through manual testing, it was shown
that the impact of recovering the additional key scopes is negligible in
most cases for both full nodes and light clients.
Due to a no longer existing bug within the wallet, it was possible for
change addresses to be created outside of their intended key scope (the
default), so wallets affected by this now need to ensure they scan the
chain for all addresses within the default key scopes (as expected), and
all _internal_ addresses (branch used for change addresses) within any
other registered key scopes to reflect their proper balance.
The commit being reverted resulted in the discovery of a bug in which
change addresses could at times be created outside of the default key
scopes, causing us to not properly determine their spends.
Previously, the wallet would determine the key scope to use for change
addresses by locating the one compatible with P2WPKH addresses, but this
wasn't always safe like in the case when multiple key scopes that
supported these addresses existed within the address manager, leading
the change address to be created outside of the intended key scope.
Normally the wallet doesn't wait for the chain backend to be synced
on regtest/simnet because there we cannot be certain if we are at
the chain tip, as there are no other nodes to compare to. For
Neutrino, this is a bit different because we rely on the cfheader
server to tell us what it thinks the chain tip is. For a wallet
recovery on Neutrino we therefore need to make sure we are at least
synced up to what the server thinks is the tip.
It was discovered that the wallet can scan the chain for unnecessary
additional addresses that are derived by higher-level applications using
custom key scopes. This isn't much of an issue for full nodes, but it
can cause light clients to scan more than what's required, triggering
more false positive matches which lead to block retrieval.
Now, we'll only scan the chain for addresses that exist within the
default key scopes, as those are the only ones the wallet should be
concerned about.
In this commit, we move the existing `internal/txsizes` package into its
own package and make it a module along the way. This allows projects
like `neutrino` to depend on a slimmer set of `btcwallet` related
dependencies.
A nil txid could've been returned from publishTransaction even if it was
successful. This was due to the underlying SendRawTransaction call
"failing", e.g., when the transaction being broadcast has already
confirmed, but publishTranasction interpreting such failure as a
success.
In this commit, we speed up creating a fresh wallet when using the btcd
backend. Before this commit, we would need to rescan 10k or so blocks
when creating a new wallet with the btcd backend. btcd will actually
fully scan all the blocks even though we have zero addresses or UTXOs to
look for. As a result, this can take quite some time.
In this commit we modify the starting height of the initial rescan to
start at the birthday height, and only modify it if it's unset, or the
best height of the chain is before this birthday height. As a result, we
won't always have the full 10k block re org safety horizon on disk, but
will tend to this level after we begin to sync forward.
Previously, the wallet would attempt to store the same block it
checkpointed during its initial sync when performing a recovery. This
would cause the previous block existence validation check to be in
place, which would ultimately fail because the previous block was not
stored intentionally.
To address this, we always start/resume our recovery from the wallet's
best height. This also ensures that we do not rescan the same block
again when resuming a recovery after a shutdown.
In this commit we fix a lingering bug in our output sanity checks that
would only show up during time periods of persistently higher fees.
Before this commit we would incorrectly use the fee rate instead of the
min relay fee when checking an output for dust. This would cause us to
mistakenly reject a transaction for having a dust output.
We fix this by falling back to using the current min-relayfee.
We use the recently introduced locateBirthdayBlock function within
birthdaySanityCheck as it serves as a more optimized alternative that
achieves the same purpose.
Currently, wallet rescans start from its known tip of the chain. Since
we no longer store blocks all the way from genesis to the tip of the
chain, performing a rescan would cause us to scan blocks all the way
from genesis, which we want to avoid. To prevent this, we set the
wallet's tip to be the current reorg safe height. This ensures that
we're unable to scan any blocks before it, and that we maintain
MaxReorgDepth blocks stored.
This commit serves as another building point to allow the wallet to not
store blocks all the way from genesis to the tip of chain. We modify the
wallet's recovery logic to now start from either its birthday block, or
the current reorg safe height if it's before the birthday, to ensure the
wallet properly only stores MaxReorgDepth blocks.
We also refactor things a bit in hopes of making the logic a bit more
readable.
We do this as the wallet will no longer store blocks all the way from
genesis to the tip of the chain. Instead, in order to find a reasonable
birthday block, we resort to performing a binary search for a block
timestamp that's within +/-2 hours of the birthday timestamp.
This serves as groundwork for only storing up to MaxReorgDepth blocks
upon initial sync. To do so, we want to make sure the chain backend
considers itself current so that we can only fetch the latest
MaxReorgDepth blocks from it.
This ensures the wallet can properly do an initial sync, a recovery, or
detect if it's on a stale branch before attempting to process new blocks
at tip.
Since the rescan will be triggered synchronously as well, we'll need to
catch the wallet's quit chan when handling rescan batches in order to
allow for clean shutdowns.