This a refactor of the btcwallet main package to create a new wallet
package.
The main feature of this package is the integration of all the other
wallet components (waddrmgr, txstore, and chain) and the Wallet type is
'runnable', so it will be continuously updating itself against changes
notified by the remote btcd instance.
It also includes several methods which provide access to information
necessary to run a wallet RPC server.
This package is used solely for the storage of private and public
keys, and the addresses they represent. Since "wallet" is an
overloaded term and a working wallet requires transaction history as
well, rename this package and its data structures to more clearly
reflect what it is for.
This change fixes the asynchronous deferred locking that used to be
performed after some timeout after a call to walletpassphrase by
managing the locked state of each account in a new account manager
goroutine. The timeouts for new unlock requests replace any running
timeouts for older requests, rather than allowing previous timeouts to
expire before the most recent one.
Fixes#105.
If the transaction store cannot be opened and read (i.e. the version
is too old to be deserialized), the wallet is marked unsynced and
rewritten, and a new empty transaction store is written over the
previous.
This change immediately writes a new empty transaction store out to
disk if the old one could not be read. Since old transaction store
versions are not read in at start, and were previously not written out
until new transaction history was received, it was possible that a
full rescan started and finished without ever marking a synced tx
history for the next wallet start.
This is an intial pass at converting the btcwallet and deps codebases
to pass a network by their parameters, rather than by a magic number
to identify the network. The parameters in params.go have been
updated to embed a *btcnet.Params, and all previous uses of cfg.Net()
have been replaced with activeNet.{Params,Net} (where activeNet is
the global var for the active network).
Although dependancy packages have not yet been updated from using
btcwire.BitcoinNet to btcnet.Params, the parameters are now accessible
at all callsites, and individual packages can be updated to use btcnet
without requiring updates in each external btc* package at once.
While here, the exported API for btcwallet internal library packages
(txstore and wallet) have been updated to pass full network parameters
rather than the btcwire definition of a network.
Calling Bytes() on a big.Int strips any leading padding zeros. This
change fixes the test to always pad the byte slice for a private key
to a length of 32.
- Instead of returning a special constructed type whenever queries for an
address. Return the internal object with an immutable external
interface.
- Make the private key gettable from PubKeyAddress to prevent having to look up
multiple times to get information from the same structure
- Enforce addresses always have public keys.
This change reappropriates the unused `last block` field from Armory's
wallet format to hold the block chain height for a partially synced
address, that is, an address that has been partially synced to
somewhere between its first seen block and the most recently seen
block. The wallet's SyncHeight method has been updated to return
partial heights as well.
The actual marking of partially unsynced address from a rescan
progress update is not implemented yet.
Now using w.IsLocked() for all instances of above.
Also changed one other place where the logic had to be reversed
in nextChainedAddress (len(w.secret) == 32 was the condition).
The private key import codepath (called when handling the
importprivkey RPC method) was not triggering rescans for the imported
address. This change begins a new rescan for each import and adds
additional logic to the wallet file to keep track of unsynced imported
addresses. After a rescan on an imported address completes, the
address is marked as in sync with the rest of wallet and future
handshake rescans will start from the last seen block, rather than the
import height of the unsynced address.
While here, improve the logging for not just import rescans, but
rescanning on btcd connect (part of the handshake) as well.
Fixes#74.
Move the stuff that scripts can't possibly support out of the interface
and move about two type assertions so that everything still works. They
key-using interfaces can be made into a KeyedAddress itnerface if we add
any more.
Add a walletAddress interface to handle the differences betweent he
different types. Stop using btcutil.AddressPubKeyHash everywhere and just use
the standard address.
Shortly we will add new types of address, so make AddressInfo an
interface, with concrete types providing address-specific information.
Adapt existing code to this new status quo.
The flag marking chained addresses as needing private keys be
generated on the next wallet unlock was not being correctly unset
after creating and encrypting the private key. After
serializing/deserializing the wallet, on next unlock, recreating
missing private keys would begin too early in the chain and fail due
to trying to encrypt an already encrypted address.
This change correctly unsets the flag and bumps the version so a
special case can be created for ignoring duplicate encryption attempts
when reading an old wallet file. Tests have also been added to the
chained pubkey test to test for this error case.
Previous to this commit, all change addresses were indistinguishable
from manually requested addresses. This adds a new function to return
the new address, setting a new change flag to true, and return the
change status with the AddressInfo.
This is needed as part of resolving #41 (getrawchangeaddress).
The exported watching wallet would include all imported addresses'
chain indexes added to the chain index map. Imported addresses are
special as they do not belong to the address chain, and this would
cause issues when serializing the wallet.
This adds a new function, ExtendActiveAddresses, to extend the number
of active addresses, generated by the address chain, by any arbitrary
positive number. This will be used for recovering wallet addresses
from a wallet backup, as well as getting the next as many addresses as
required to keep a watching wallet in sync with an original wallet
with the private keys, or sync an original wallet with new addresses
generated by the watching wallet.
This change introduces a new function to export a wallet in memory to
a watching wallet. Watching wallets allow to watch for balance
changes and transactions to wallet addresses while only storing the
public parts of a wallet (no private keys). New addresses created by
the watching wallet will use pubkey address chaining and will allow to
receive funds to an indefinite number of new addresses, and create the
private keys for said addresses from the non-watching wallet later.
The actual exporting of a watching wallet to a file (triggered by an
RPC request) is not yet implemented.
While here, fix an issue found by new test code for the chained
address code which incorrectly set the starting index of addresses in
the chain needing private keys to be created.
This change adds a check for a valid (32-byte length) secret before
attempting to encrypt or decrypt any addresses. If the check fails, a
meaningful error (ErrWalletLocked) is returned to the caller, rather
than an error out of the aes package.
This function was not implemented (returning zero values) and all
versioning is handled internally by the wallet's ReadFrom and WriteTo
functions. If the read wallet does not match the latest file version,
it is read in the old format, but always written back with the new
format.
The wallet package was using a sync.Mutex around the saved decryption
key (kept in memory for an unlocked wallet). As the wallet package is
designed to use no internal locking, and correct synchronization is
provided by the importers of the package, this mutex has been removed.
This change uses the ChainedPubKey function to create addresses from
the previous address's public key and the wallet chaincode, without
the need for the private key, if the keypool has been depleted and the
wallet is locked. This is done since the next chained private key is
unsolvable without a locked wallet.
If a wallet contains any of these chained addresses with missing
private keys, the private keys are created during the next wallet
unlock, using ChainedPrivKey.