// Copyright (c) 2013-2016 The btcsuite developers // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package chain import ( "errors" "sync" "time" "github.com/lbryio/lbcd/btcjson" "github.com/lbryio/lbcd/chaincfg" "github.com/lbryio/lbcd/chaincfg/chainhash" "github.com/lbryio/lbcd/rpcclient" "github.com/lbryio/lbcd/wire" btcutil "github.com/lbryio/lbcutil" "github.com/lbryio/lbcutil/gcs" "github.com/lbryio/lbcutil/gcs/builder" "github.com/lbryio/lbcwallet/waddrmgr" "github.com/lbryio/lbcwallet/wtxmgr" ) // RPCClient represents a persistent client connection to a bitcoin RPC server // for information regarding the current best block chain. type RPCClient struct { *rpcclient.Client connConfig *rpcclient.ConnConfig // Work around unexported field chainParams *chaincfg.Params reconnectAttempts int enqueueNotification chan interface{} dequeueNotification chan interface{} currentBlock chan *waddrmgr.BlockStamp quit chan struct{} wg sync.WaitGroup started bool quitMtx sync.Mutex } // NewRPCClient creates a client connection to the server described by the // connect string. If disableTLS is false, the remote RPC certificate must be // provided in the certs slice. The connection is not established immediately, // but must be done using the Start method. If the remote server does not // operate on the same bitcoin network as described by the passed chain // parameters, the connection will be disconnected. func NewRPCClient(chainParams *chaincfg.Params, connect, user, pass string, certs []byte, disableTLS bool, skipverify bool, reconnectAttempts int) (*RPCClient, error) { if reconnectAttempts < 0 { return nil, errors.New("reconnectAttempts must be positive") } client := &RPCClient{ connConfig: &rpcclient.ConnConfig{ Host: connect, Endpoint: "ws", User: user, Pass: pass, Certificates: certs, DisableAutoReconnect: false, DisableConnectOnNew: true, DisableTLS: disableTLS, SkipVerify: skipverify, }, chainParams: chainParams, reconnectAttempts: reconnectAttempts, enqueueNotification: make(chan interface{}), dequeueNotification: make(chan interface{}), currentBlock: make(chan *waddrmgr.BlockStamp), quit: make(chan struct{}), } ntfnCallbacks := &rpcclient.NotificationHandlers{ OnClientConnected: client.onClientConnect, OnBlockConnected: client.onBlockConnected, OnBlockDisconnected: client.onBlockDisconnected, OnRecvTx: client.onRecvTx, OnRedeemingTx: client.onRedeemingTx, OnRescanFinished: client.onRescanFinished, OnRescanProgress: client.onRescanProgress, } rpcClient, err := rpcclient.New(client.connConfig, ntfnCallbacks) if err != nil { return nil, err } client.Client = rpcClient return client, nil } // BackEnd returns the name of the driver. func (c *RPCClient) BackEnd() string { return "lbcd" } // Start attempts to establish a client connection with the remote server. // If successful, handler goroutines are started to process notifications // sent by the server. After a limited number of connection attempts, this // function gives up, and therefore will not block forever waiting for the // connection to be established to a server that may not exist. func (c *RPCClient) Start() error { err := c.Connect(c.reconnectAttempts) if err != nil { return err } // Verify that the server is running on the expected network. net, err := c.GetCurrentNet() if err != nil { c.Disconnect() return err } if net != c.chainParams.Net { c.Disconnect() return errors.New("mismatched networks") } c.quitMtx.Lock() c.started = true c.quitMtx.Unlock() c.wg.Add(1) go c.handler() return nil } // Stop disconnects the client and signals the shutdown of all goroutines // started by Start. func (c *RPCClient) Stop() { c.quitMtx.Lock() select { case <-c.quit: default: close(c.quit) c.Client.Shutdown() if !c.started { close(c.dequeueNotification) } } c.quitMtx.Unlock() } // IsCurrent returns whether the chain backend considers its view of the network // as "current". func (c *RPCClient) IsCurrent() bool { bestHash, _, err := c.GetBestBlock() if err != nil { return false } bestHeader, err := c.GetBlockHeader(bestHash) if err != nil { return false } return bestHeader.Timestamp.After(time.Now().Add(-isCurrentDelta)) } // Rescan wraps the normal Rescan command with an additional parameter that // allows us to map an outpoint to the address in the chain that it pays to. // This is useful when using BIP 158 filters as they include the prev pkScript // rather than the full outpoint. func (c *RPCClient) Rescan(startHash *chainhash.Hash, addrs []btcutil.Address, outPoints map[wire.OutPoint]btcutil.Address) error { flatOutpoints := make([]*wire.OutPoint, 0, len(outPoints)) for ops := range outPoints { ops := ops flatOutpoints = append(flatOutpoints, &ops) } return c.Client.Rescan(startHash, addrs, flatOutpoints) // nolint:staticcheck } // WaitForShutdown blocks until both the client has finished disconnecting // and all handlers have exited. func (c *RPCClient) WaitForShutdown() { c.Client.WaitForShutdown() c.wg.Wait() } // Notifications returns a channel of parsed notifications sent by the remote // bitcoin RPC server. This channel must be continually read or the process // may abort for running out memory, as unread notifications are queued for // later reads. func (c *RPCClient) Notifications() <-chan interface{} { return c.dequeueNotification } // BlockStamp returns the latest block notified by the client, or an error // if the client has been shut down. func (c *RPCClient) BlockStamp() (*waddrmgr.BlockStamp, error) { select { case bs := <-c.currentBlock: return bs, nil case <-c.quit: return nil, errors.New("disconnected") } } // FilterBlocks scans the blocks contained in the FilterBlocksRequest for any // addresses of interest. For each requested block, the corresponding compact // filter will first be checked for matches, skipping those that do not report // anything. If the filter returns a positive match, the full block will be // fetched and filtered. This method returns a FilterBlocksResponse for the first // block containing a matching address. If no matches are found in the range of // blocks requested, the returned response will be nil. func (c *RPCClient) FilterBlocks( req *FilterBlocksRequest) (*FilterBlocksResponse, error) { blockFilterer := NewBlockFilterer(c.chainParams, req) // Construct the watchlist using the addresses and outpoints contained // in the filter blocks request. watchList, err := buildFilterBlocksWatchList(req) if err != nil { return nil, err } // Iterate over the requested blocks, fetching the compact filter for // each one, and matching it against the watchlist generated above. If // the filter returns a positive match, the full block is then requested // and scanned for addresses using the block filterer. for i, blk := range req.Blocks { rawFilter, err := c.GetCFilter(&blk.Hash, wire.GCSFilterRegular) if err != nil { return nil, err } // Ensure the filter is large enough to be deserialized. if len(rawFilter.Data) < 4 { continue } filter, err := gcs.FromNBytes( builder.DefaultP, builder.DefaultM, rawFilter.Data, ) if err != nil { return nil, err } // Skip any empty filters. if filter.N() == 0 { continue } key := builder.DeriveKey(&blk.Hash) matched, err := filter.MatchAny(key, watchList) if err != nil { return nil, err } else if !matched { continue } log.Infof("Fetching block height=%d hash=%v", blk.Height, blk.Hash) rawBlock, err := c.GetBlock(&blk.Hash) if err != nil { return nil, err } if !blockFilterer.FilterBlock(rawBlock) { continue } // If any external or internal addresses were detected in this // block, we return them to the caller so that the rescan // windows can widened with subsequent addresses. The // `BatchIndex` is returned so that the caller can compute the // *next* block from which to begin again. resp := &FilterBlocksResponse{ BatchIndex: uint32(i), BlockMeta: blk, FoundExternalAddrs: blockFilterer.FoundExternal, FoundInternalAddrs: blockFilterer.FoundInternal, FoundOutPoints: blockFilterer.FoundOutPoints, RelevantTxns: blockFilterer.RelevantTxns, } return resp, nil } // No addresses were found for this range. return nil, nil } // parseBlock parses a btcws definition of the block a tx is mined it to the // Block structure of the wtxmgr package, and the block index. This is done // here since rpcclient doesn't parse this nicely for us. func parseBlock(block *btcjson.BlockDetails) (*wtxmgr.BlockMeta, error) { if block == nil { return nil, nil } blkHash, err := chainhash.NewHashFromStr(block.Hash) if err != nil { return nil, err } blk := &wtxmgr.BlockMeta{ Block: wtxmgr.Block{ Height: block.Height, Hash: *blkHash, }, Time: time.Unix(block.Time, 0), } return blk, nil } func (c *RPCClient) onClientConnect() { select { case c.enqueueNotification <- ClientConnected{}: case <-c.quit: } } func (c *RPCClient) onBlockConnected(hash *chainhash.Hash, height int32, time time.Time) { select { case c.enqueueNotification <- BlockConnected{ Block: wtxmgr.Block{ Hash: *hash, Height: height, }, Time: time, }: case <-c.quit: } } func (c *RPCClient) onBlockDisconnected(hash *chainhash.Hash, height int32, time time.Time) { select { case c.enqueueNotification <- BlockDisconnected{ Block: wtxmgr.Block{ Hash: *hash, Height: height, }, Time: time, }: case <-c.quit: } } func (c *RPCClient) onRecvTx(tx *btcutil.Tx, block *btcjson.BlockDetails) { blk, err := parseBlock(block) if err != nil { // Log and drop improper notification. log.Errorf("recvtx notification bad block: %v", err) return } rec, err := wtxmgr.NewTxRecordFromMsgTx(tx.MsgTx(), time.Now()) if err != nil { log.Errorf("Cannot create transaction record for relevant "+ "tx: %v", err) return } select { case c.enqueueNotification <- RelevantTx{rec, blk}: case <-c.quit: } } func (c *RPCClient) onRedeemingTx(tx *btcutil.Tx, block *btcjson.BlockDetails) { // Handled exactly like recvtx notifications. c.onRecvTx(tx, block) } func (c *RPCClient) onRescanProgress(hash *chainhash.Hash, height int32, blkTime time.Time) { select { case c.enqueueNotification <- &RescanProgress{hash, height, blkTime}: case <-c.quit: } } func (c *RPCClient) onRescanFinished(hash *chainhash.Hash, height int32, blkTime time.Time) { select { case c.enqueueNotification <- &RescanFinished{hash, height, blkTime}: case <-c.quit: } } // handler maintains a queue of notifications and the current state (best // block) of the chain. func (c *RPCClient) handler() { hash, height, err := c.GetBestBlock() if err != nil { log.Errorf("Failed to receive best block from chain server: %v", err) c.Stop() c.wg.Done() return } bs := &waddrmgr.BlockStamp{Hash: *hash, Height: height} // TODO: Rather than leaving this as an unbounded queue for all types of // notifications, try dropping ones where a later enqueued notification // can fully invalidate one waiting to be processed. For example, // blockconnected notifications for greater block heights can remove the // need to process earlier blockconnected notifications still waiting // here. var notifications []interface{} enqueue := c.enqueueNotification var dequeue chan interface{} var next interface{} out: for { select { case n, ok := <-enqueue: if !ok { // If no notifications are queued for handling, // the queue is finished. if len(notifications) == 0 { break out } // nil channel so no more reads can occur. enqueue = nil continue } if len(notifications) == 0 { next = n dequeue = c.dequeueNotification } notifications = append(notifications, n) case dequeue <- next: if n, ok := next.(BlockConnected); ok { bs = &waddrmgr.BlockStamp{ Height: n.Height, Hash: n.Hash, } } notifications[0] = nil notifications = notifications[1:] if len(notifications) != 0 { next = notifications[0] } else { // If no more notifications can be enqueued, the // queue is finished. if enqueue == nil { break out } dequeue = nil } case c.currentBlock <- bs: case <-c.quit: break out } } c.Stop() close(c.dequeueNotification) c.wg.Done() } // POSTClient creates the equivalent HTTP POST rpcclient.Client. func (c *RPCClient) POSTClient() (*rpcclient.Client, error) { configCopy := *c.connConfig configCopy.HTTPPostMode = true return rpcclient.New(&configCopy, nil) }