lbcwallet/legacy/txstore/json.go

199 lines
5.7 KiB
Go
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Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
/*
* Copyright (c) 2013, 2014 Conformal Systems LLC <info@conformal.com>
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
package txstore
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
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import (
"github.com/btcsuite/btcd/blockchain"
"github.com/btcsuite/btcd/btcjson"
"github.com/btcsuite/btcd/chaincfg"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcutil"
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
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)
// ToJSON returns a slice of btcjson listtransactions result types for all credits
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
// and debits of this transaction.
func (t *TxRecord) ToJSON(account string, chainHeight int32,
net *chaincfg.Params) ([]btcjson.ListTransactionsResult, error) {
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
t.s.mtx.RLock()
defer t.s.mtx.RUnlock()
results := []btcjson.ListTransactionsResult{}
if d, err := t.Debits(); err == nil {
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
r, err := d.toJSON(account, chainHeight, net)
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
if err != nil {
return nil, err
}
results = r
}
for _, c := range t.Credits() {
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
r, err := c.toJSON(account, chainHeight, net)
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
if err != nil {
return nil, err
}
results = append(results, r)
}
return results, nil
}
// ToJSON returns a slice of objects that may be marshaled as a JSON array
// of JSON objects for a listtransactions RPC reply.
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
func (d Debits) ToJSON(account string, chainHeight int32,
net *chaincfg.Params) ([]btcjson.ListTransactionsResult, error) {
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
d.s.mtx.RLock()
defer d.s.mtx.RUnlock()
return d.toJSON(account, chainHeight, net)
}
func (d Debits) toJSON(account string, chainHeight int32,
net *chaincfg.Params) ([]btcjson.ListTransactionsResult, error) {
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
msgTx := d.Tx().MsgTx()
reply := make([]btcjson.ListTransactionsResult, 0, len(msgTx.TxOut))
for _, txOut := range msgTx.TxOut {
address := ""
_, addrs, _, _ := txscript.ExtractPkScriptAddrs(txOut.PkScript, net)
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
if len(addrs) == 1 {
address = addrs[0].EncodeAddress()
}
result := btcjson.ListTransactionsResult{
Account: account,
Address: address,
Category: "send",
Amount: btcutil.Amount(-txOut.Value).ToBTC(),
Fee: d.Fee().ToBTC(),
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
TxID: d.Tx().Sha().String(),
Time: d.txRecord.received.Unix(),
TimeReceived: d.txRecord.received.Unix(),
WalletConflicts: []string{},
}
if d.BlockHeight != -1 {
b, err := d.s.lookupBlock(d.BlockHeight)
if err != nil {
return nil, err
}
result.BlockHash = b.Hash.String()
result.BlockIndex = int64(d.Tx().Index())
result.BlockTime = b.Time.Unix()
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
result.Confirmations = int64(confirms(d.BlockHeight, chainHeight))
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
}
reply = append(reply, result)
}
return reply, nil
}
// CreditCategory describes the type of wallet transaction output. The category
// of "sent transactions" (debits) is always "send", and is not expressed by
// this type.
type CreditCategory int
// These constants define the possible credit categories.
const (
CreditReceive CreditCategory = iota
CreditGenerate
CreditImmature
)
// Category returns the category of the credit. The passed block chain height is
// used to distinguish immature from mature coinbase outputs.
func (c *Credit) Category(chainHeight int32) CreditCategory {
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
c.s.mtx.RLock()
defer c.s.mtx.RUnlock()
return c.category(chainHeight)
}
func (c *Credit) category(chainHeight int32) CreditCategory {
if c.isCoinbase() {
if confirmed(blockchain.CoinbaseMaturity, c.BlockHeight, chainHeight) {
return CreditGenerate
}
return CreditImmature
}
return CreditReceive
}
// String returns the category as a string. This string may be used as the
// JSON string for categories as part of listtransactions and gettransaction
// RPC responses.
func (c CreditCategory) String() string {
switch c {
case CreditReceive:
return "receive"
case CreditGenerate:
return "generate"
case CreditImmature:
return "immature"
default:
return "unknown"
}
}
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
// ToJSON returns a slice of objects that may be marshaled as a JSON array
// of JSON objects for a listtransactions RPC reply.
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
func (c Credit) ToJSON(account string, chainHeight int32,
net *chaincfg.Params) (btcjson.ListTransactionsResult, error) {
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
c.s.mtx.RLock()
defer c.s.mtx.RUnlock()
return c.toJSON(account, chainHeight, net)
}
func (c Credit) toJSON(account string, chainHeight int32,
net *chaincfg.Params) (btcjson.ListTransactionsResult, error) {
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
msgTx := c.Tx().MsgTx()
txout := msgTx.TxOut[c.OutputIndex]
var address string
_, addrs, _, _ := txscript.ExtractPkScriptAddrs(txout.PkScript, net)
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
if len(addrs) == 1 {
address = addrs[0].EncodeAddress()
}
result := btcjson.ListTransactionsResult{
Account: account,
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
Category: c.category(chainHeight).String(),
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
Address: address,
Amount: btcutil.Amount(txout.Value).ToBTC(),
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
TxID: c.Tx().Sha().String(),
Time: c.received.Unix(),
TimeReceived: c.received.Unix(),
WalletConflicts: []string{},
}
if c.BlockHeight != -1 {
b, err := c.s.lookupBlock(c.BlockHeight)
if err != nil {
return btcjson.ListTransactionsResult{}, err
}
result.BlockHash = b.Hash.String()
result.BlockIndex = int64(c.Tx().Index())
result.BlockTime = b.Time.Unix()
Remove account support, fix races on btcd connect. This commit is the result of several big changes being made to the wallet. In particular, the "handshake" (initial sync to the chain server) was quite racy and required proper synchronization. To make fixing this race easier, several other changes were made to the internal wallet data structures and much of the RPC server ended up being rewritten. First, all account support has been removed. The previous Account struct has been replaced with a Wallet structure, which includes a keystore for saving keys, and a txstore for storing relevant transactions. This decision has been made since it is the opinion of myself and other developers that bitcoind accounts are fundamentally broken (as accounts implemented by bitcoind support both arbitrary address groupings as well as moving balances between accounts -- these are fundamentally incompatible features), and since a BIP0032 keystore is soon planned to be implemented (at which point, "accounts" can return as HD extended keys). With the keystore handling the grouping of related keys, there is no reason have many different Account structs, and the AccountManager has been removed as well. All RPC handlers that take an account option will only work with "" (the default account) or "*" if the RPC allows specifying all accounts. Second, much of the RPC server has been cleaned up. The global variables for the RPC server and chain server client have been moved to part of the rpcServer struct, and the handlers for each RPC method that are looked up change depending on which components have been set. Passthrough requests are also no longer handled specially, but when the chain server is set, a handler to perform the passthrough will be returned if the method is not otherwise a wallet RPC. The notification system for websocket clients has also been rewritten so wallet components can send notifications through channels, rather than requiring direct access to the RPC server itself, or worse still, sending directly to a websocket client's send channel. In the future, this will enable proper registration of notifications, rather than unsolicited broadcasts to every connected websocket client (see issue #84). Finally, and the main reason why much of this cleanup was necessary, the races during intial sync with the chain server have been fixed. Previously, when the 'Handshake' was run, a rescan would occur which would perform modifications to Account data structures as notifications were received. Synchronization was provided with a single binary semaphore which serialized all access to wallet and account data. However, the Handshake itself was not able to run with this lock (or else notifications would block), and many data races would occur as both notifications were being handled. If GOMAXPROCS was ever increased beyond 1, btcwallet would always immediately crash due to invalid addresses caused by the data races on startup. To fix this, the single lock for all wallet access has been replaced with mutexes for both the keystore and txstore. Handling of btcd notifications and client requests may now occur simultaneously. GOMAXPROCS has also been set to the number of logical CPUs at the beginning of main, since with the data races fixed, there's no reason to prevent the extra parallelism gained by increasing it. Closes #78. Closes #101. Closes #110.
2014-07-09 05:17:38 +02:00
result.Confirmations = int64(confirms(c.BlockHeight, chainHeight))
Another day, another tx store implementation. The last transaction store was a great example of how not to write scalable software. For a variety of reasons, it was very slow at processing transaction inserts. Among them: 1) Every single transaction record being saved in a linked list (container/list), and inserting into this list would be an O(n) operation so that records could be ordered by receive date. 2) Every single transaction in the above mentioned list was iterated over in order to find double spends which must be removed. It is silly to do this check for mined transactions, which already have been checked for this by btcd. Worse yet, if double spends were found, the list would be iterated a second (or third, or fourth) time for each removed transaction. 3) All spend tracking for signed-by-wallet transactions was found on each transaction insert, even if the now spent previous transaction outputs were known by the caller. This list could keep going on, but you get the idea. It was bad. To resolve these issues a new transaction store had to be implemented. The new implementation: 1) Tracks mined and unmined transactions in different data structures. Mined transactions are cheap to track because the required double spend checks have already been performed by the chain server, and double spend checks are only required to be performed on newly-inserted mined transactions which may conflict with previous unmined transactions. 2) Saves mined transactions grouped by block first, and then by their transaction index. Lookup keys for mined transactions are simply the block height (in the best chain, that's all we save) and index of the transaction in the block. This makes looking up any arbitrary transaction almost an O(1) operation (almost, because block height and block indexes are mapped to their slice indexes with a Go map). 3) Saves records in each transaction for whether the outputs are wallet credits (spendable by wallet) and for whether inputs debit from previous credits. Both structures point back to the source or spender (credits point to the transaction that spends them, or nil for unspent credits, and debits include keys to lookup the transaction credits they spent. While complicated to keep track of, this greatly simplifies the spent tracking for transactions across rollbacks and transaction removals. 4) Implements double spend checking as an almost O(1) operation. A Go map is used to map each previous outpoint for all unconfirmed transactions to the unconfirmed tx record itself. Checking for double spends on confirmed transaction inserts only involves looking up each previous outpoint of the inserted tx in this map. If a double spend is found, removal is simplified by only removing the transaction and its spend chain from store maps, rather than iterating a linked list several times over to remove each dead transaction in the spend chain. 5) Allows the caller to specify the previous credits which are spent by a debiting transaction. When a transaction is created by wallet, the previous outputs are already known, and by passing their record types to the AddDebits method, lookups for each previously unspent credit are omitted. 6) Bookkeeps all blocks with transactions with unspent credits, and bookkeeps the transaction indexes of all transactions with unspent outputs for a single block. For the case where the caller adding a debit record does not know what credits a transaction debits from, these bookkeeping structures allow the store to only consider known unspent transactions, rather than searching through both spent and unspents. 7) Saves amount deltas for the entire balance as a result of each block, due to transactions within that block. This improves the performance of calculating the full balance by not needing to iterate over every transaction, and then every credit, to determine if a credit is spent or unspent. When transactions are moved from unconfirmed to a block structure, the amount deltas are incremented by the amount of all transaction credits (both spent and unspent) and debited by the total amount the transaction spends from previous wallet credits. For the common case of calculating a balance with just one confirmation, the only involves iterating over each block structure and adding the (possibly negative) amount delta. Coinbase rewards are saved similarly, but with a different amount variable so they can be seperatly included or excluded. Due to all of the changes in how the store internally works, the serialization format has changed. To simplify the serialization logic, support for reading the last store file version has been removed. Past this change, a rescan (run automatically) will be required to rebuild the transaction history.
2014-05-05 23:12:05 +02:00
}
return result, nil
}