package channeldb import ( "bytes" "encoding/binary" "image/color" "io" "net" "time" "github.com/boltdb/bolt" "github.com/lightningnetwork/lnd/lnwire" "github.com/roasbeef/btcd/btcec" "github.com/roasbeef/btcd/chaincfg/chainhash" "github.com/roasbeef/btcd/wire" "github.com/roasbeef/btcutil" ) var ( // nodeBucket is a bucket which houses all the vertices or nodes within // the channel graph. This bucket has a single-sub bucket which adds an // additional index from pubkey -> alias. Within the top-level of this // bucket, the key space maps a node's compressed public key to the // serialized information for that node. Additionally, there's a // special key "source" which stores the pubkey of the source node. The // source node is used as the starting point for all graph/queries and // traversals. The graph is formed as a star-graph with the source node // at the center. // // maps: pubKey -> nofInfo // maps: source -> selfPubKey nodeBucket = []byte("graph-node") // sourceKey is a special key that resides within the nodeBucket. The // sourceKey maps a key to the public key of the "self node". sourceKey = []byte("source") // aliasIndexBucket is a sub-bucket that's nested within the main // nodeBucket. This bucket maps the public key of a node to it's // current alias. This bucket is provided as it can be used within a // future UI layer to add an additional degree of confirmation. aliasIndexBucket = []byte("alias") // edgeBucket is a bucket which houses all of the edge or channel // information within the channel graph. This bucket essentially acts // as an adjacency list, which in conjunction with a range scan, can be // used to iterate over all the _outgoing_ edges for a particular node. // Key in the bucket use a prefix scheme which leads with the node's // public key and sends with the compact edge ID. For each edgeID, // there will be two entries within the bucket, as the graph is // directed: nodes may have different policies w.r.t to fees for their // respective directions. // // maps: pubKey || edgeID -> edge policy for node edgeBucket = []byte("graph-edge") // chanStart is an array of all zero bytes which is used to perform // range scans within the edgeBucket to obtain all of the outgoing // edges for a particular node. chanStart [8]byte // edgeIndexBucket is an index which can be used to iterate all edges // in the bucket, grouping them according to their in/out nodes. // Additionally, the items in this bucket also contain the complete // edge information for a channel. The edge information includes the // capacity of the channel, the nodes that made the channel, etc. This // bucket resides within the edgeBucket above. Creation of a edge // proceeds in two phases: first the edge is added to the edge index, // afterwards the edgeBucket can be updated with the latest details of // the edge as they are announced on the network. // // maps: chanID -> pubKey1 || pubKey2 || restofEdgeInfo edgeIndexBucket = []byte("edge-index") // channelPointBucket maps a channel's full outpoint (txid:index) to // its short 8-byte channel ID. This bucket resides within the // edgeBucket above, and can be used to quickly remove an edge due to // the outpoint being spent, or to query for existence of a channel. // // maps: outPoint -> chanID channelPointBucket = []byte("chan-index") // graphMetaBucket is a top-level bucket which stores various meta-deta // related to the on-disk channel graph. Data stored in this bucket // includes the block to which the graph has been synced to, the total // number of channels, etc. graphMetaBucket = []byte("graph-meta") // pruneTipKey is a key within the above graphMetaBucket that stores // the best known blockhash+height that the channel graph has been // known to be pruned to. Once a new block is discovered, any channels // that have been closed (by spending the outpoint) can safely be // removed from the graph. pruneTipKey = []byte("prune-tip") edgeBloomKey = []byte("edge-bloom") nodeBloomKey = []byte("node-bloom") ) // ChannelGraph is a persistent, on-disk graph representation of the Lightning // Network. This struct can be used to implement path finding algorithms on top // of, and also to update a node's view based on information received from the // p2p network. Internally, the graph is stored using a modified adjacency list // representation with some added object interaction possible with each // serialized edge/node. The graph is stored is directed, meaning that are two // edges stored for each channel: an inbound/outbound edge for each node pair. // Nodes, edges, and edge information can all be added to the graph // independently. Edge removal results in the deletion of all edge information // for that edge. type ChannelGraph struct { db *DB // TODO(roasbeef): store and update bloom filter to reduce disk access // due to current gossip model // * LRU cache for edges? } // addressType specifies the network protocol and version that should be used // when connecting to a node at a particular address. type addressType uint8 const ( tcp4Addr addressType = 0 tcp6Addr addressType = 1 onionAddr addressType = 2 ) // ForEachChannel iterates through all the channel edges stored within the // graph and invokes the passed callback for each edge. The callback takes two // edges as since this is a directed graph, both the in/out edges are visited. // If the callback returns an error, then the transaction is aborted and the // iteration stops early. // // NOTE: If an edge can't be found, or wasn't advertised, then a nil pointer // for that particular channel edge routing policy will be passed into the // callback. func (c *ChannelGraph) ForEachChannel(cb func(*ChannelEdgeInfo, *ChannelEdgePolicy, *ChannelEdgePolicy) error) error { // TODO(roasbeef): ptr map to reduce # of allocs? no duplicates return c.db.View(func(tx *bolt.Tx) error { // First, grab the node bucket. This will be used to populate // the Node pointers in each edge read from disk. nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNotFound } // Next, grab the edge bucket which stores the edges, and also // the index itself so we can group the directed edges together // logically. edges := tx.Bucket(edgeBucket) if edges == nil { return ErrGraphNoEdgesFound } edgeIndex := edges.Bucket(edgeIndexBucket) if edgeIndex == nil { return ErrGraphNoEdgesFound } // For each edge pair within the edge index, we fetch each edge // itself and also the node information in order to fully // populated the object. return edgeIndex.ForEach(func(chanID, edgeInfoBytes []byte) error { infoReader := bytes.NewReader(edgeInfoBytes) edgeInfo, err := deserializeChanEdgeInfo(infoReader) if err != nil { return err } // The first node is contained within the first half of // the edge information. node1Pub := edgeInfoBytes[:33] edge1, err := fetchChanEdgePolicy(edges, chanID, node1Pub, nodes) if err != nil && err != ErrEdgeNotFound && err != ErrGraphNodeNotFound { return err } // The targeted edge may have not been advertised // within the network, so we ensure it's non-nil before // deferencing its attributes. if edge1 != nil { edge1.db = c.db if edge1.Node != nil { edge1.Node.db = c.db } } // Similarly, the second node is contained within the // latter half of the edge information. node2Pub := edgeInfoBytes[33:] edge2, err := fetchChanEdgePolicy(edges, chanID, node2Pub, nodes) if err != nil && err != ErrEdgeNotFound && err != ErrGraphNodeNotFound { return err } // The targeted edge may have not been advertised // within the network, so we ensure it's non-nil before // deferencing its attributes. if edge2 != nil { edge2.db = c.db if edge2.Node != nil { edge2.Node.db = c.db } } // With both edges read, execute the call back. IF this // function returns an error then the transaction will // be aborted. return cb(edgeInfo, edge1, edge2) }) }) } // ForEachNode iterates through all the stored vertices/nodes in the graph, // executing the passed callback with each node encountered. If the callback // returns an error, then the transaction is aborted and the iteration stops // early. // // If the caller wishes to re-use an existing boltdb transaction, then it // should be passed as the first argument. Otherwise the first argument should // be nil and a fresh transaction will be created to execute the graph // traversal // // TODO(roasbeef): add iterator interface to allow for memory efficient graph // traversal when graph gets mega func (c *ChannelGraph) ForEachNode(tx *bolt.Tx, cb func(*bolt.Tx, *LightningNode) error) error { traversal := func(tx *bolt.Tx) error { // First grab the nodes bucket which stores the mapping from // pubKey to node information. nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNotFound } return nodes.ForEach(func(pubKey, nodeBytes []byte) error { // If this is the source key, then we skip this // iteration as the value for this key is a pubKey // rather than raw node information. if bytes.Equal(pubKey, sourceKey) || len(pubKey) != 33 { return nil } nodeReader := bytes.NewReader(nodeBytes) node, err := deserializeLightningNode(nodeReader) if err != nil { return err } node.db = c.db // Execute the callback, the transaction will abort if // this returns an error. return cb(tx, node) }) } // If no transaction was provided, then we'll create a new transaction // to execute the transaction within. if tx == nil { return c.db.View(traversal) } // Otherwise, we re-use the existing transaction to execute the graph // traversal. return traversal(tx) } // SourceNode returns the source node of the graph. The source node is treated // as the center node within a star-graph. This method may be used to kick off // a path finding algorithm in order to explore the reachability of another // node based off the source node. func (c *ChannelGraph) SourceNode() (*LightningNode, error) { var source *LightningNode err := c.db.View(func(tx *bolt.Tx) error { // First grab the nodes bucket which stores the mapping from // pubKey to node information. nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNotFound } selfPub := nodes.Get(sourceKey) if selfPub == nil { return ErrSourceNodeNotSet } // With the pubKey of the source node retrieved, we're able to // fetch the full node information. node, err := fetchLightningNode(nodes, selfPub) if err != nil { return err } source = node source.db = c.db return nil }) if err != nil { return nil, err } return source, nil } // SetSourceNode sets the source node within the graph database. The source // node is to be used as the center of a star-graph within path finding // algorithms. func (c *ChannelGraph) SetSourceNode(node *LightningNode) error { nodePub := node.PubKey.SerializeCompressed() return c.db.Update(func(tx *bolt.Tx) error { // First grab the nodes bucket which stores the mapping from // pubKey to node information. nodes, err := tx.CreateBucketIfNotExists(nodeBucket) if err != nil { return err } // Next we create the mapping from source to the targeted // public key. if err := nodes.Put(sourceKey, nodePub); err != nil { return err } // Finally, we commit the information of the lightning node // itself. return addLightningNode(tx, node) }) } // AddLightningNode adds a vertex/node to the graph database. If the node is not // in the database from before, this will add a new, unconnected one to the // graph. If it is present from before, this will update that node's // information. Note that this method is expected to only be called to update // an already present node from a node annoucement, or to insert a node found // in a channel update. // // TODO(roasbeef): also need sig of announcement func (c *ChannelGraph) AddLightningNode(node *LightningNode) error { return c.db.Update(func(tx *bolt.Tx) error { return addLightningNode(tx, node) }) } func addLightningNode(tx *bolt.Tx, node *LightningNode) error { nodes, err := tx.CreateBucketIfNotExists(nodeBucket) if err != nil { return err } aliases, err := nodes.CreateBucketIfNotExists(aliasIndexBucket) if err != nil { return err } return putLightningNode(nodes, aliases, node) } // LookupAlias attempts to return the alias as advertised by the target node. // TODO(roasbeef): currently assumes that aliases are unique... func (c *ChannelGraph) LookupAlias(pub *btcec.PublicKey) (string, error) { var alias string err := c.db.View(func(tx *bolt.Tx) error { nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNodesNotFound } aliases := nodes.Bucket(aliasIndexBucket) if aliases == nil { return ErrGraphNodesNotFound } nodePub := pub.SerializeCompressed() a := aliases.Get(nodePub) if a == nil { return ErrNodeAliasNotFound } // TODO(roasbeef): should actually be using the utf-8 // package... alias = string(a) return nil }) if err != nil { return "", err } return alias, nil } // DeleteLightningNode removes a vertex/node from the database according to the // node's public key. func (c *ChannelGraph) DeleteLightningNode(nodePub *btcec.PublicKey) error { pub := nodePub.SerializeCompressed() // TODO(roasbeef): ensure dangling edges are removed... return c.db.Update(func(tx *bolt.Tx) error { nodes, err := tx.CreateBucketIfNotExists(nodeBucket) if err != nil { return err } aliases, err := tx.CreateBucketIfNotExists(aliasIndexBucket) if err != nil { return err } if err := aliases.Delete(pub); err != nil { return err } return nodes.Delete(pub) }) } // AddChannelEdge adds a new (undirected, blank) edge to the graph database. An // undirected edge from the two target nodes are created. The information // stored denotes the static attributes of the channel, such as the channelID, // the keys involved in creation of the channel, and the set of features that // the channel supports. The chanPoint and chanID are used to uniquely identify // the edge globally within the database. func (c *ChannelGraph) AddChannelEdge(edge *ChannelEdgeInfo) error { // Construct the channel's primary key which is the 8-byte channel ID. var chanKey [8]byte binary.BigEndian.PutUint64(chanKey[:], edge.ChannelID) return c.db.Update(func(tx *bolt.Tx) error { edges, err := tx.CreateBucketIfNotExists(edgeBucket) if err != nil { return err } edgeIndex, err := edges.CreateBucketIfNotExists(edgeIndexBucket) if err != nil { return err } chanIndex, err := edges.CreateBucketIfNotExists(channelPointBucket) if err != nil { return err } // First, attempt to check if this edge has already been // created. If so, then we can exit early as this method is // meant to be idempotent. if edgeInfo := edgeIndex.Get(chanKey[:]); edgeInfo != nil { return ErrEdgeAlreadyExist } // If the edge hasn't been created yet, then we'll first add it // to the edge index in order to associate the edge between two // nodes and also store the static components of the channel. if err := putChanEdgeInfo(edgeIndex, edge, chanKey); err != nil { return err } // Finally we add it to the channel index which maps channel // points (outpoints) to the shorter channel ID's. var b bytes.Buffer if err := writeOutpoint(&b, &edge.ChannelPoint); err != nil { return err } return chanIndex.Put(b.Bytes(), chanKey[:]) }) } // HasChannelEdge returns true if the database knows of a channel edge with the // passed channel ID, and false otherwise. If the an edge with that ID is found // within the graph, then two time stamps representing the last time the edge // was updated for both directed edges are returned along with the boolean. func (c *ChannelGraph) HasChannelEdge(chanID uint64) (time.Time, time.Time, bool, error) { // TODO(roasbeef): check internal bloom filter first var ( node1UpdateTime time.Time node2UpdateTime time.Time exists bool ) if err := c.db.View(func(tx *bolt.Tx) error { edges := tx.Bucket(edgeBucket) if edges == nil { return ErrGraphNoEdgesFound } edgeIndex := edges.Bucket(edgeIndexBucket) if edgeIndex == nil { return ErrGraphNoEdgesFound } var channelID [8]byte byteOrder.PutUint64(channelID[:], chanID) if edgeIndex.Get(channelID[:]) == nil { exists = false return nil } exists = true // If the channel has been found in the graph, then retrieve // the edges itself so we can return the last updated // timestmaps. nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNodeNotFound } e1, e2, err := fetchChanEdgePolicies(edgeIndex, edges, nodes, channelID[:], c.db) if err != nil { return err } // As we may have only one of the edges populated, only set the // update time if the edge was found in the database. if e1 != nil { node1UpdateTime = e1.LastUpdate } if e2 != nil { node2UpdateTime = e2.LastUpdate } return nil }); err != nil { return time.Time{}, time.Time{}, exists, err } return node1UpdateTime, node2UpdateTime, exists, nil } // UpdateChannelEdge retrieves and update edge of the graph database. Method // only reserved for updating an edge info after it's already been created. // In order to maintain this constraints, we return an error in the scenario // that an edge info hasn't yet been created yet, but someone attempts to update // it. func (c *ChannelGraph) UpdateChannelEdge(edge *ChannelEdgeInfo) error { // Construct the channel's primary key which is the 8-byte channel ID. var chanKey [8]byte binary.BigEndian.PutUint64(chanKey[:], edge.ChannelID) return c.db.Update(func(tx *bolt.Tx) error { edges, err := tx.CreateBucketIfNotExists(edgeBucket) if err != nil { return err } edgeIndex, err := edges.CreateBucketIfNotExists(edgeIndexBucket) if err != nil { return err } if edgeInfo := edgeIndex.Get(chanKey[:]); edgeInfo == nil { return ErrEdgeNotFound } return putChanEdgeInfo(edgeIndex, edge, chanKey) }) } const ( // pruneTipBytes is the total size of the value which stores the // current prune tip of the graph. The prune tip indicates if the // channel graph is in sync with the current UTXO state. The structure // is: blockHash || blockHeight, taking 36 bytes total. pruneTipBytes = 32 + 4 ) // PruneGraph prunes newly closed channels from the channel graph in response // to a new block being solved on the network. Any transactions which spend the // funding output of any known channels within he graph will be deleted. // Additionally, the "prune tip", or the last block which has been used to // prune the graph is stored so callers can ensure the graph is fully in sync // with the current UTXO state. A slice of channels that have been closed by // the target block are returned if the function succeeds without error. func (c *ChannelGraph) PruneGraph(spentOutputs []*wire.OutPoint, blockHash *chainhash.Hash, blockHeight uint32) ([]*ChannelEdgeInfo, error) { var chansClosed []*ChannelEdgeInfo err := c.db.Update(func(tx *bolt.Tx) error { // First grab the edges bucket which houses the information // we'd like to delete edges, err := tx.CreateBucketIfNotExists(edgeBucket) if err != nil { return err } // Next grab the two edge indexes which will also need to be updated. edgeIndex, err := edges.CreateBucketIfNotExists(edgeIndexBucket) if err != nil { return err } chanIndex, err := edges.CreateBucketIfNotExists(channelPointBucket) if err != nil { return err } // For each of the outpoints that've been spent within the // block, we attempt to delete them from the graph as if that // outpoint was a channel, then it has now been closed. for _, chanPoint := range spentOutputs { // TODO(roasbeef): load channel bloom filter, continue // if NOT if filter var opBytes bytes.Buffer if err := writeOutpoint(&opBytes, chanPoint); err != nil { return nil } // First attempt to see if the channel exists within // the database, if not, then we can exit early. chanID := chanIndex.Get(opBytes.Bytes()) if chanID == nil { continue } // However, if it does, then we'll read out the full // version so we can add it to the set of deleted // channels. edgeInfo, err := fetchChanEdgeInfo(edgeIndex, chanID) if err != nil { return err } chansClosed = append(chansClosed, edgeInfo) // Attempt to delete the channel, an ErrEdgeNotFound // will be returned if that outpoint isn't known to be // a channel. If no error is returned, then a channel // was successfully pruned. err = delChannelByEdge(edges, edgeIndex, chanIndex, chanPoint) if err != nil && err != ErrEdgeNotFound { return err } } metaBucket, err := tx.CreateBucketIfNotExists(graphMetaBucket) if err != nil { return err } // With the graph pruned, update the current "prune tip" which // can be used to check if the graph is fully synced with the // current UTXO state. var newTip [pruneTipBytes]byte copy(newTip[:], blockHash[:]) byteOrder.PutUint32(newTip[32:], blockHeight) return metaBucket.Put(pruneTipKey, newTip[:]) }) if err != nil { return nil, err } return chansClosed, nil } // PruneTip returns the block height and hash of the latest block that has been // used to prune channels in the graph. Knowing the "prune tip" allows callers // to tell if the graph is currently in sync with the current best known UTXO // state. func (c *ChannelGraph) PruneTip() (*chainhash.Hash, uint32, error) { var ( currentTip [pruneTipBytes]byte tipHash chainhash.Hash tipHeight uint32 ) err := c.db.View(func(tx *bolt.Tx) error { graphMeta := tx.Bucket(graphMetaBucket) if graphMeta == nil { return ErrGraphNotFound } tipBytes := graphMeta.Get(pruneTipKey) if tipBytes == nil { return ErrGraphNeverPruned } copy(currentTip[:], tipBytes) return nil }) if err != nil { return nil, 0, err } // Once we have the prune tip, the first 32 bytes are the block hash, // with the latter 4 bytes being the block height. copy(tipHash[:], currentTip[:32]) tipHeight = byteOrder.Uint32(currentTip[32:]) return &tipHash, tipHeight, nil } // DeleteChannelEdge removes an edge from the database as identified by it's // funding outpoint. If the edge does not exist within the database, then // ErrEdgeNotFound will be returned. func (c *ChannelGraph) DeleteChannelEdge(chanPoint *wire.OutPoint) error { // TODO(roasbeef): possibly delete from node bucket if node has no more // channels // TODO(roasbeef): don't delete both edges? return c.db.Update(func(tx *bolt.Tx) error { // First grab the edges bucket which houses the information // we'd like to delete edges, err := tx.CreateBucketIfNotExists(edgeBucket) if err != nil { return err } // Next grab the two edge indexes which will also need to be updated. edgeIndex, err := edges.CreateBucketIfNotExists(edgeIndexBucket) if err != nil { return err } chanIndex, err := edges.CreateBucketIfNotExists(channelPointBucket) if err != nil { return err } return delChannelByEdge(edges, edgeIndex, chanIndex, chanPoint) }) } // ChannelID attempt to lookup the 8-byte compact channel ID which maps to the // passed channel point (outpoint). If the passed channel doesn't exist within // the database, then ErrEdgeNotFound is returned. func (c *ChannelGraph) ChannelID(chanPoint *wire.OutPoint) (uint64, error) { var chanID uint64 var b bytes.Buffer if err := writeOutpoint(&b, chanPoint); err != nil { return 0, nil } if err := c.db.View(func(tx *bolt.Tx) error { edges := tx.Bucket(edgeBucket) if edges == nil { return ErrGraphNoEdgesFound } chanIndex := edges.Bucket(channelPointBucket) if chanIndex == nil { return ErrGraphNoEdgesFound } chanIDBytes := chanIndex.Get(b.Bytes()) if chanIDBytes == nil { return ErrEdgeNotFound } chanID = byteOrder.Uint64(chanIDBytes) return nil }); err != nil { return 0, err } return chanID, nil } func delChannelByEdge(edges *bolt.Bucket, edgeIndex *bolt.Bucket, chanIndex *bolt.Bucket, chanPoint *wire.OutPoint) error { var b bytes.Buffer if err := writeOutpoint(&b, chanPoint); err != nil { return err } // If the channel's outpoint doesn't exist within the outpoint // index, then the edge does not exist. chanID := chanIndex.Get(b.Bytes()) if chanID == nil { return ErrEdgeNotFound } // Otherwise we obtain the two public keys from the mapping: // chanID -> pubKey1 || pubKey2. With this, we can construct // the keys which house both of the directed edges for this // channel. nodeKeys := edgeIndex.Get(chanID) // The edge key is of the format pubKey || chanID. First we // construct the latter half, populating the channel ID. var edgeKey [33 + 8]byte copy(edgeKey[33:], chanID) // With the latter half constructed, copy over the first public // key to delete the edge in this direction, then the second to // delete the edge in the opposite direction. copy(edgeKey[:33], nodeKeys[:33]) if edges.Get(edgeKey[:]) != nil { if err := edges.Delete(edgeKey[:]); err != nil { return err } } copy(edgeKey[:33], nodeKeys[33:]) if edges.Get(edgeKey[:]) != nil { if err := edges.Delete(edgeKey[:]); err != nil { return err } } // Finally, with the edge data deleted, we can purge the // information from the two edge indexes. if err := edgeIndex.Delete(chanID); err != nil { return err } return chanIndex.Delete(b.Bytes()) } // UpdateEdgePolicy updates the edge routing policy for a single directed edge // within the database for the referenced channel. The `flags` attribute within // the ChannelEdgePolicy determines which of the directed edges are being // updated. If the flag is 1, then the first node's information is being // updated, otherwise it's the second node's information. The node ordering is // determined tby the lexicographical ordering of the identity public keys of // the nodes on either side of the channel. func (c *ChannelGraph) UpdateEdgePolicy(edge *ChannelEdgePolicy) error { return c.db.Update(func(tx *bolt.Tx) error { edges, err := tx.CreateBucketIfNotExists(edgeBucket) if err != nil { return err } edgeIndex, err := edges.CreateBucketIfNotExists(edgeIndexBucket) if err != nil { return err } // Create the channelID key be converting the channel ID // integer into a byte slice. var chanID [8]byte byteOrder.PutUint64(chanID[:], edge.ChannelID) // With the channel ID, we then fetch the value storing the two // nodes which connect this channel edge. nodeInfo := edgeIndex.Get(chanID[:]) if nodeInfo == nil { return ErrEdgeNotFound } // Depending on the flags value passed above, either the first // or second edge policy is being updated. var fromNode, toNode []byte if edge.Flags == 0 { fromNode = nodeInfo[:33] toNode = nodeInfo[33:67] } else { fromNode = nodeInfo[33:67] toNode = nodeInfo[:33] } // Finally, with the direction of the edge being updated // identified, we update the on-disk edge representation. return putChanEdgePolicy(edges, edge, fromNode, toNode) }) } // LightningNode represents an individual vertex/node within the channel graph. // A node is connected to other nodes by one or more channel edges emanating // from it. As the graph is directed, a node will also have an incoming edge // attached to it for each outgoing edge. type LightningNode struct { // PubKey is the node's long-term identity public key. This key will be // used to authenticated any advertisements/updates sent by the node. PubKey *btcec.PublicKey // HaveNodeAnnouncement indicates whether we received a node annoucement // for this particular node. If true, the remaining fields will be set, // if false only the PubKey is known for this node. HaveNodeAnnouncement bool // LastUpdate is the last time the vertex information for this node has // been updated. LastUpdate time.Time // Address is the TCP address this node is reachable over. Addresses []net.Addr // Color is the selected color for the node. Color color.RGBA // Alias is a nick-name for the node. The alias can be used to confirm // a node's identity or to serve as a short ID for an address book. Alias string // AuthSig is a signature under the advertised public key which serves // to authenticate the attributes announced by this node. // // TODO(roasbeef): hook into serialization once full verification is in AuthSig *btcec.Signature // Features is the list of protocol features supported by this node. Features *lnwire.FeatureVector db *DB // TODO(roasbeef): discovery will need storage to keep it's last IP // address and re-announce if interface changes? // TODO(roasbeef): add update method and fetch? } // FetchLightningNode attempts to look up a target node by its identity public // key. If the node isn't found in the database, then ErrGraphNodeNotFound is // returned. func (c *ChannelGraph) FetchLightningNode(pub *btcec.PublicKey) (*LightningNode, error) { var node *LightningNode nodePub := pub.SerializeCompressed() err := c.db.View(func(tx *bolt.Tx) error { // First grab the nodes bucket which stores the mapping from // pubKey to node information. nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNotFound } // If a key for this serialized public key isn't found, then // the target node doesn't exist within the database. nodeBytes := nodes.Get(nodePub) if nodeBytes == nil { return ErrGraphNodeNotFound } // If the node is found, then we can de deserialize the node // information to return to the user. nodeReader := bytes.NewReader(nodeBytes) n, err := deserializeLightningNode(nodeReader) if err != nil { return err } n.db = c.db node = n return nil }) if err != nil { return nil, err } return node, nil } // HasLightningNode determines if the graph has a vertex identified by the // target node identity public key. If the node exists in the database, a // timestamp of when the data for the node was lasted updated is returned along // with a true boolean. Otherwise, an empty time.Time is returned with a false // boolean. func (c *ChannelGraph) HasLightningNode(pub *btcec.PublicKey) (time.Time, bool, error) { var ( updateTime time.Time exists bool ) nodePub := pub.SerializeCompressed() err := c.db.View(func(tx *bolt.Tx) error { // First grab the nodes bucket which stores the mapping from // pubKey to node information. nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNotFound } // If a key for this serialized public key isn't found, we can // exit early. nodeBytes := nodes.Get(nodePub) if nodeBytes == nil { exists = false return nil } // Otherwise we continue on to obtain the time stamp // representing the last time the data for this node was // updated. nodeReader := bytes.NewReader(nodeBytes) node, err := deserializeLightningNode(nodeReader) if err != nil { return err } exists = true updateTime = node.LastUpdate return nil }) if err != nil { return time.Time{}, exists, nil } return updateTime, exists, nil } // ForEachChannel iterates through all the outgoing channel edges from this // node, executing the passed callback with each edge as its sole argument. The // first edge policy is the outgoing edge *to* the connecting node, while the // second is the incoming edge *from* the connecting node. If the callback // returns an error, then the iteration is halted with the error propagated // back up to the caller. // // If the caller wishes to re-use an existing boltdb transaction, then it // should be passed as the first argument. Otherwise the first argument should // be nil and a fresh transaction will be created to execute the graph // traversal. func (l *LightningNode) ForEachChannel(tx *bolt.Tx, cb func(*bolt.Tx, *ChannelEdgeInfo, *ChannelEdgePolicy, *ChannelEdgePolicy) error) error { nodePub := l.PubKey.SerializeCompressed() traversal := func(tx *bolt.Tx) error { nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNotFound } edges := tx.Bucket(edgeBucket) if edges == nil { return ErrGraphNotFound } edgeIndex := edges.Bucket(edgeIndexBucket) if edgeIndex == nil { return ErrGraphNoEdgesFound } // In order to reach all the edges for this node, we take // advantage of the construction of the key-space within the // edge bucket. The keys are stored in the form: pubKey || // chanID. Therefore, starting from a chanID of zero, we can // scan forward in the bucket, grabbing all the edges for the // node. Once the prefix no longer matches, then we know we're // done. var nodeStart [33 + 8]byte copy(nodeStart[:], nodePub) copy(nodeStart[33:], chanStart[:]) // Starting from the key pubKey || 0, we seek forward in the // bucket until the retrieved key no longer has the public key // as its prefix. This indicates that we've stepped over into // another node's edges, so we can terminate our scan. edgeCursor := edges.Cursor() for nodeEdge, edgeInfo := edgeCursor.Seek(nodeStart[:]); bytes.HasPrefix(nodeEdge, nodePub); nodeEdge, edgeInfo = edgeCursor.Next() { // If the prefix still matches, then the value is the // raw edge information. So we can now serialize the // edge info and fetch the outgoing node in order to // retrieve the full channel edge. edgeReader := bytes.NewReader(edgeInfo) toEdgePolicy, err := deserializeChanEdgePolicy(edgeReader, nodes) if err != nil { return err } toEdgePolicy.db = l.db toEdgePolicy.Node.db = l.db chanID := nodeEdge[33:] edgeInfo, err := fetchChanEdgeInfo(edgeIndex, chanID) if err != nil { return err } // We'll also fetch the incoming edge so this // information can be available to the caller. incomingNode := toEdgePolicy.Node.PubKey.SerializeCompressed() fromEdgePolicy, err := fetchChanEdgePolicy( edges, chanID, incomingNode, nodes, ) if err != nil && err != ErrEdgeNotFound && err != ErrGraphNodeNotFound { return err } if fromEdgePolicy != nil { fromEdgePolicy.db = l.db if fromEdgePolicy.Node != nil { fromEdgePolicy.Node.db = l.db } } // Finally, we execute the callback. err = cb(tx, edgeInfo, toEdgePolicy, fromEdgePolicy) if err != nil { return err } } return nil } // If no transaction was provided, then we'll create a new transaction // to execute the transaction within. if tx == nil { return l.db.View(traversal) } // Otherwise, we re-use the existing transaction to execute the graph // traversal. return traversal(tx) } // ChannelEdgeInfo represents a fully authenticated channel along with all its // unique attributes. Once an authenticated channel announcement has been // processed on the network, then a instance of ChannelEdgeInfo encapsulating // the channels attributes is stored. The other portions relevant to routing // policy of a channel are stored within a ChannelEdgePolicy for each direction // of the channel. type ChannelEdgeInfo struct { // ChannelID is the unique channel ID for the channel. The first 3 // bytes are the block height, the next 3 the index within the block, // and the last 2 bytes are the output index for the channel. ChannelID uint64 // ChainHash is the hash that uniquely identifies the chain that this // channel was opened within. // // TODO(roasbeef): need to modify db keying for multi-chain // * must add chain hash to prefix as well ChainHash chainhash.Hash // NodeKey1 is the identity public key of the "first" node that was // involved in the creation of this channel. A node is considered // "first" if the lexicographical ordering the its serialized public // key is "smaller" than that of the other node involved in channel // creation. NodeKey1 *btcec.PublicKey // NodeKey2 is the identity public key of the "second" node that was // involved in the creation of this channel. A node is considered // "second" if the lexicographical ordering the its serialized public // key is "larger" than that of the other node involved in channel // creation. NodeKey2 *btcec.PublicKey // BitcoinKey1 is the Bitcoin multi-sig key belonging to the first // node, that was involved in the funding transaction that originally // created the channel that this struct represents. BitcoinKey1 *btcec.PublicKey // BitcoinKey2 is the Bitcoin multi-sig key belonging to the second // node, that was involved in the funding transaction that originally // created the channel that this struct represents. BitcoinKey2 *btcec.PublicKey // Features is an opaque byte slice that encodes the set of channel // specific features that this channel edge supports. Features []byte // AuthProof is the authentication proof for this channel. This proof // contains a set of signatures binding four identities, which attests // to the legitimacy of the advertised channel. AuthProof *ChannelAuthProof // ChannelPoint is the funding outpoint of the channel. This can be // used to uniquely identify the channel within the channel graph. ChannelPoint wire.OutPoint // Capacity is the total capacity of the channel, this is determined by // the value output in the outpoint that created this channel. Capacity btcutil.Amount } // ChannelAuthProof is the authentication proof (the signature portion) for a // channel. Using the four signatures contained in the struct, and some // axillary knowledge (the funding script, node identities, and outpoint) nodes // on the network are able to validate the authenticity and existence of a // channel. Each of these signatures signs the following digest: chanID || // nodeID1 || nodeID2 || bitcoinKey1|| bitcoinKey2 || 2-byte-feature-len || // features. type ChannelAuthProof struct { // NodeSig1 is the signature using the identity key of the node that is // first in a lexicographical ordering of the serialized public keys of // the two nodes that created the channel. NodeSig1 *btcec.Signature // NodeSig2 is the signature using the identity key of the node that is // second in a lexicographical ordering of the serialized public keys // of the two nodes that created the channel. NodeSig2 *btcec.Signature // BitcoinSig1 is the signature using the public key of the first node // that was used in the channel's multi-sig output. BitcoinSig1 *btcec.Signature // BitcoinSig2 is the signature using the public key of the second node // that was used in the channel's multi-sig output. BitcoinSig2 *btcec.Signature } // IsEmpty check is the authentication proof is empty Proof is empty if at // least one of the signatures are equal to nil. func (p *ChannelAuthProof) IsEmpty() bool { return p.NodeSig1 == nil || p.NodeSig2 == nil || p.BitcoinSig1 == nil || p.BitcoinSig2 == nil } // ChannelEdgePolicy represents a *directed* edge within the channel graph. For // each channel in the database, there are two distinct edges: one for each // possible direction of travel along the channel. The edges themselves hold // information concerning fees, and minimum time-lock information which is // utilized during path finding. type ChannelEdgePolicy struct { // Signature is a channel announcement signature, which is needed for // proper edge policy announcement. Signature *btcec.Signature // ChannelID is the unique channel ID for the channel. The first 3 // bytes are the block height, the next 3 the index within the block, // and the last 2 bytes are the output index for the channel. ChannelID uint64 // LastUpdate is the last time an authenticated edge for this channel // was received. LastUpdate time.Time // Flags is a bitfield which signals the capabilities of the channel as // well as the directed edge this update applies to. // TODO(roasbeef): make into wire struct Flags uint16 // TimeLockDelta is the number of blocks this node will subtract from // the expiry of an incoming HTLC. This value expresses the time buffer // the node would like to HTLC exchanges. TimeLockDelta uint16 // MinHTLC is the smallest value HTLC this node will accept, expressed // in millisatoshi. MinHTLC lnwire.MilliSatoshi // FeeBaseMSat is the base HTLC fee that will be charged for forwarding // ANY HTLC, expressed in mSAT's. FeeBaseMSat lnwire.MilliSatoshi // FeeProportionalMillionths is the rate that the node will charge for // HTLCs for each millionth of a satoshi forwarded. FeeProportionalMillionths lnwire.MilliSatoshi // Node is the LightningNode that this directed edge leads to. Using // this pointer the channel graph can further be traversed. Node *LightningNode db *DB } // FetchChannelEdgesByOutpoint attempts to lookup the two directed edges for // the channel identified by the funding outpoint. If the channel can't be // found, then ErrEdgeNotFound is returned. A struct which houses the general // information for the channel itself is returned as well as two structs that // contain the routing policies for the channel in either direction. func (c *ChannelGraph) FetchChannelEdgesByOutpoint(op *wire.OutPoint) (*ChannelEdgeInfo, *ChannelEdgePolicy, *ChannelEdgePolicy, error) { var ( edgeInfo *ChannelEdgeInfo policy1 *ChannelEdgePolicy policy2 *ChannelEdgePolicy ) err := c.db.Update(func(tx *bolt.Tx) error { // First, grab the node bucket. This will be used to populate // the Node pointers in each edge read from disk. nodes, err := tx.CreateBucketIfNotExists(nodeBucket) if err != nil { return err } // Next, grab the edge bucket which stores the edges, and also // the index itself so we can group the directed edges together // logically. edges, err := tx.CreateBucketIfNotExists(edgeBucket) if err != nil { return err } edgeIndex, err := edges.CreateBucketIfNotExists(edgeIndexBucket) if err != nil { return err } // If the channel's outpoint doesn't exist within the outpoint // index, then the edge does not exist. chanIndex, err := edges.CreateBucketIfNotExists(channelPointBucket) if err != nil { return err } var b bytes.Buffer if err := writeOutpoint(&b, op); err != nil { return err } chanID := chanIndex.Get(b.Bytes()) if chanID == nil { return ErrEdgeNotFound } // If the channel is found to exists, then we'll first retrieve // the general information for the channel. edge, err := fetchChanEdgeInfo(edgeIndex, chanID) if err != nil { return err } edgeInfo = edge // Once we have the information about the channels' parameters, // we'll fetch the routing policies for each for the directed // edges. e1, e2, err := fetchChanEdgePolicies(edgeIndex, edges, nodes, chanID, c.db) if err != nil { return err } policy1 = e1 policy2 = e2 return nil }) if err != nil { return nil, nil, nil, err } return edgeInfo, policy1, policy2, nil } // FetchChannelEdgesByID attempts to lookup the two directed edges for the // channel identified by the channel ID. If the channel can't be found, then // ErrEdgeNotFound is returned. A struct which houses the general information // for the channel itself is returned as well as two structs that contain the // routing policies for the channel in either direction. func (c *ChannelGraph) FetchChannelEdgesByID(chanID uint64) (*ChannelEdgeInfo, *ChannelEdgePolicy, *ChannelEdgePolicy, error) { var ( edgeInfo *ChannelEdgeInfo policy1 *ChannelEdgePolicy policy2 *ChannelEdgePolicy channelID [8]byte ) err := c.db.View(func(tx *bolt.Tx) error { // First, grab the node bucket. This will be used to populate // the Node pointers in each edge read from disk. nodes := tx.Bucket(nodeBucket) if nodes == nil { return ErrGraphNotFound } // Next, grab the edge bucket which stores the edges, and also // the index itself so we can group the directed edges together // logically. edges := tx.Bucket(edgeBucket) if edges == nil { return ErrGraphNoEdgesFound } edgeIndex := edges.Bucket(edgeIndexBucket) if edgeIndex == nil { return ErrGraphNoEdgesFound } byteOrder.PutUint64(channelID[:], chanID) edge, err := fetchChanEdgeInfo(edgeIndex, channelID[:]) if err != nil { return err } edgeInfo = edge e1, e2, err := fetchChanEdgePolicies(edgeIndex, edges, nodes, channelID[:], c.db) if err != nil { return err } policy1 = e1 policy2 = e2 return nil }) if err != nil { return nil, nil, nil, err } return edgeInfo, policy1, policy2, nil } // ChannelView returns the verifiable edge information for each active channel // within the known channel graph. The set of UTXO's returned are the ones that // need to be watched on chain to detect channel closes on the resident // blockchain. func (c *ChannelGraph) ChannelView() ([]wire.OutPoint, error) { var chanPoints []wire.OutPoint if err := c.db.View(func(tx *bolt.Tx) error { // We're going to iterate over the entire channel index, so // we'll need to fetch the edgeBucket to get to the index as // it's a sub-bucket. edges := tx.Bucket(edgeBucket) if edges == nil { return ErrGraphNoEdgesFound } chanIndex := edges.Bucket(channelPointBucket) if chanIndex == nil { return ErrGraphNoEdgesFound } // Once we have the proper bucket, we'll range over each key // (which is the channel point for the channel) and decode it, // accumulating each entry. return chanIndex.ForEach(func(chanPointBytes, _ []byte) error { chanPointReader := bytes.NewReader(chanPointBytes) var chanPoint wire.OutPoint err := readOutpoint(chanPointReader, &chanPoint) if err != nil { return err } chanPoints = append(chanPoints, chanPoint) return nil }) }); err != nil { return nil, err } return chanPoints, nil } // NewChannelEdgePolicy returns a new blank ChannelEdgePolicy. func (c *ChannelGraph) NewChannelEdgePolicy() *ChannelEdgePolicy { return &ChannelEdgePolicy{db: c.db} } func putLightningNode(nodeBucket *bolt.Bucket, aliasBucket *bolt.Bucket, node *LightningNode) error { var ( scratch [16]byte b bytes.Buffer ) nodePub := node.PubKey.SerializeCompressed() // If the node has the update time set, write it, else write 0. updateUnix := uint64(0) if node.LastUpdate.Unix() > 0 { updateUnix = uint64(node.LastUpdate.Unix()) } byteOrder.PutUint64(scratch[:8], updateUnix) if _, err := b.Write(scratch[:8]); err != nil { return err } if _, err := b.Write(nodePub); err != nil { return err } // If we got a node announcement for this node, we will have the rest of // the data available. If not we don't have more data to write. if !node.HaveNodeAnnouncement { // Write HaveNodeAnnouncement=0. byteOrder.PutUint16(scratch[:2], 0) if _, err := b.Write(scratch[:2]); err != nil { return err } return nodeBucket.Put(nodePub, b.Bytes()) } // Write HaveNodeAnnouncement=1. byteOrder.PutUint16(scratch[:2], 1) if _, err := b.Write(scratch[:2]); err != nil { return err } if err := binary.Write(&b, byteOrder, node.Color.R); err != nil { return err } if err := binary.Write(&b, byteOrder, node.Color.G); err != nil { return err } if err := binary.Write(&b, byteOrder, node.Color.B); err != nil { return err } if err := wire.WriteVarString(&b, 0, node.Alias); err != nil { return err } if err := node.Features.Encode(&b); err != nil { return err } numAddresses := uint16(len(node.Addresses)) byteOrder.PutUint16(scratch[:2], numAddresses) if _, err := b.Write(scratch[:2]); err != nil { return err } for _, address := range node.Addresses { if address.Network() == "tcp" { if address.(*net.TCPAddr).IP.To4() != nil { scratch[0] = uint8(tcp4Addr) if _, err := b.Write(scratch[:1]); err != nil { return err } copy(scratch[:4], address.(*net.TCPAddr).IP.To4()) if _, err := b.Write(scratch[:4]); err != nil { return err } } else { scratch[0] = uint8(tcp6Addr) if _, err := b.Write(scratch[:1]); err != nil { return err } copy(scratch[:], address.(*net.TCPAddr).IP.To16()) if _, err := b.Write(scratch[:]); err != nil { return err } } byteOrder.PutUint16(scratch[:2], uint16(address.(*net.TCPAddr).Port)) if _, err := b.Write(scratch[:2]); err != nil { return err } } } err := wire.WriteVarBytes(&b, 0, node.AuthSig.Serialize()) if err != nil { return err } if err := aliasBucket.Put(nodePub, []byte(node.Alias)); err != nil { return err } return nodeBucket.Put(nodePub, b.Bytes()) } func fetchLightningNode(nodeBucket *bolt.Bucket, nodePub []byte) (*LightningNode, error) { nodeBytes := nodeBucket.Get(nodePub) if nodeBytes == nil { return nil, ErrGraphNodeNotFound } nodeReader := bytes.NewReader(nodeBytes) return deserializeLightningNode(nodeReader) } func deserializeLightningNode(r io.Reader) (*LightningNode, error) { node := &LightningNode{} var scratch [8]byte if _, err := r.Read(scratch[:]); err != nil { return nil, err } unix := int64(byteOrder.Uint64(scratch[:])) node.LastUpdate = time.Unix(unix, 0) var pub [33]byte if _, err := r.Read(pub[:]); err != nil { return nil, err } var err error node.PubKey, err = btcec.ParsePubKey(pub[:], btcec.S256()) if err != nil { return nil, err } if _, err := r.Read(scratch[:2]); err != nil { return nil, err } hasNodeAnn := byteOrder.Uint16(scratch[:2]) if hasNodeAnn == 1 { node.HaveNodeAnnouncement = true } else { node.HaveNodeAnnouncement = false } // The rest of the data is optional, and will only be there if we got a node // announcement for this node. if !node.HaveNodeAnnouncement { return node, nil } // We did get a node announcement for this node, so we'll have the rest // of the data available. if err := binary.Read(r, byteOrder, &node.Color.R); err != nil { return nil, err } if err := binary.Read(r, byteOrder, &node.Color.G); err != nil { return nil, err } if err := binary.Read(r, byteOrder, &node.Color.B); err != nil { return nil, err } node.Alias, err = wire.ReadVarString(r, 0) if err != nil { return nil, err } node.Features, err = lnwire.NewFeatureVectorFromReader(r) if err != nil { return nil, err } if _, err := r.Read(scratch[:2]); err != nil { return nil, err } numAddresses := int(byteOrder.Uint16(scratch[:2])) var addresses []net.Addr for i := 0; i < numAddresses; i++ { var address net.Addr if _, err := r.Read(scratch[:1]); err != nil { return nil, err } // TODO(roasbeef): also add onion addrs switch addressType(scratch[0]) { case tcp4Addr: addr := &net.TCPAddr{} var ip [4]byte if _, err := r.Read(ip[:]); err != nil { return nil, err } addr.IP = (net.IP)(ip[:]) if _, err := r.Read(scratch[:2]); err != nil { return nil, err } addr.Port = int(byteOrder.Uint16(scratch[:2])) address = addr case tcp6Addr: addr := &net.TCPAddr{} var ip [16]byte if _, err := r.Read(ip[:]); err != nil { return nil, err } addr.IP = (net.IP)(ip[:]) if _, err := r.Read(scratch[:2]); err != nil { return nil, err } addr.Port = int(byteOrder.Uint16(scratch[:2])) address = addr default: return nil, ErrUnknownAddressType } addresses = append(addresses, address) } node.Addresses = addresses sigBytes, err := wire.ReadVarBytes(r, 0, 80, "sig") if err != nil { return nil, err } node.AuthSig, err = btcec.ParseSignature(sigBytes, btcec.S256()) if err != nil { return nil, err } return node, nil } func putChanEdgeInfo(edgeIndex *bolt.Bucket, edgeInfo *ChannelEdgeInfo, chanID [8]byte) error { var b bytes.Buffer if _, err := b.Write(edgeInfo.NodeKey1.SerializeCompressed()); err != nil { return err } if _, err := b.Write(edgeInfo.NodeKey2.SerializeCompressed()); err != nil { return err } if _, err := b.Write(edgeInfo.BitcoinKey1.SerializeCompressed()); err != nil { return err } if _, err := b.Write(edgeInfo.BitcoinKey2.SerializeCompressed()); err != nil { return err } if err := wire.WriteVarBytes(&b, 0, edgeInfo.Features); err != nil { return err } authProof := edgeInfo.AuthProof var nodeSig1, nodeSig2, bitcoinSig1, bitcoinSig2 []byte if authProof != nil { nodeSig1 = authProof.NodeSig1.Serialize() nodeSig2 = authProof.NodeSig2.Serialize() bitcoinSig1 = authProof.BitcoinSig1.Serialize() bitcoinSig2 = authProof.BitcoinSig2.Serialize() } if err := wire.WriteVarBytes(&b, 0, nodeSig1); err != nil { return err } if err := wire.WriteVarBytes(&b, 0, nodeSig2); err != nil { return err } if err := wire.WriteVarBytes(&b, 0, bitcoinSig1); err != nil { return err } if err := wire.WriteVarBytes(&b, 0, bitcoinSig2); err != nil { return err } if err := writeOutpoint(&b, &edgeInfo.ChannelPoint); err != nil { return err } if err := binary.Write(&b, byteOrder, uint64(edgeInfo.Capacity)); err != nil { return err } if _, err := b.Write(chanID[:]); err != nil { return err } if _, err := b.Write(edgeInfo.ChainHash[:]); err != nil { return err } return edgeIndex.Put(chanID[:], b.Bytes()) } func fetchChanEdgeInfo(edgeIndex *bolt.Bucket, chanID []byte) (*ChannelEdgeInfo, error) { edgeInfoBytes := edgeIndex.Get(chanID) if edgeInfoBytes == nil { return nil, ErrEdgeNotFound } edgeInfoReader := bytes.NewReader(edgeInfoBytes) return deserializeChanEdgeInfo(edgeInfoReader) } func deserializeChanEdgeInfo(r io.Reader) (*ChannelEdgeInfo, error) { var ( err error pubKeyBytes [33]byte edgeInfo = &ChannelEdgeInfo{} ) readKey := func() (*btcec.PublicKey, error) { if _, err := io.ReadFull(r, pubKeyBytes[:]); err != nil { return nil, err } return btcec.ParsePubKey(pubKeyBytes[:], btcec.S256()) } edgeInfo.NodeKey1, err = readKey() if err != nil { return nil, err } edgeInfo.NodeKey2, err = readKey() if err != nil { return nil, err } edgeInfo.BitcoinKey1, err = readKey() if err != nil { return nil, err } edgeInfo.BitcoinKey2, err = readKey() if err != nil { return nil, err } edgeInfo.Features, err = wire.ReadVarBytes(r, 0, 900, "features") if err != nil { return nil, err } proof := &ChannelAuthProof{} readSig := func() (*btcec.Signature, error) { sigBytes, err := wire.ReadVarBytes(r, 0, 80, "sigs") if err != nil { return nil, err } if len(sigBytes) != 0 { return btcec.ParseSignature(sigBytes, btcec.S256()) } return nil, nil } proof.NodeSig1, err = readSig() if err != nil { return nil, err } proof.NodeSig2, err = readSig() if err != nil { return nil, err } proof.BitcoinSig1, err = readSig() if err != nil { return nil, err } proof.BitcoinSig2, err = readSig() if err != nil { return nil, err } if !proof.IsEmpty() { edgeInfo.AuthProof = proof } edgeInfo.ChannelPoint = wire.OutPoint{} if err := readOutpoint(r, &edgeInfo.ChannelPoint); err != nil { return nil, err } if err := binary.Read(r, byteOrder, &edgeInfo.Capacity); err != nil { return nil, err } if err := binary.Read(r, byteOrder, &edgeInfo.ChannelID); err != nil { return nil, err } if _, err := io.ReadFull(r, edgeInfo.ChainHash[:]); err != nil { return nil, err } return edgeInfo, nil } func putChanEdgePolicy(edges *bolt.Bucket, edge *ChannelEdgePolicy, from, to []byte) error { var edgeKey [33 + 8]byte copy(edgeKey[:], from) byteOrder.PutUint64(edgeKey[33:], edge.ChannelID) var b bytes.Buffer err := wire.WriteVarBytes(&b, 0, edge.Signature.Serialize()) if err != nil { return err } if err := binary.Write(&b, byteOrder, edge.ChannelID); err != nil { return err } var scratch [8]byte updateUnix := uint64(edge.LastUpdate.Unix()) byteOrder.PutUint64(scratch[:], updateUnix) if _, err := b.Write(scratch[:]); err != nil { return err } if err := binary.Write(&b, byteOrder, edge.Flags); err != nil { return err } if err := binary.Write(&b, byteOrder, edge.TimeLockDelta); err != nil { return err } if err := binary.Write(&b, byteOrder, uint64(edge.MinHTLC)); err != nil { return err } if err := binary.Write(&b, byteOrder, uint64(edge.FeeBaseMSat)); err != nil { return err } if err := binary.Write(&b, byteOrder, uint64(edge.FeeProportionalMillionths)); err != nil { return err } if _, err := b.Write(to); err != nil { return err } return edges.Put(edgeKey[:], b.Bytes()[:]) } func fetchChanEdgePolicy(edges *bolt.Bucket, chanID []byte, nodePub []byte, nodes *bolt.Bucket) (*ChannelEdgePolicy, error) { var edgeKey [33 + 8]byte copy(edgeKey[:], nodePub) copy(edgeKey[33:], chanID[:]) edgeBytes := edges.Get(edgeKey[:]) if edgeBytes == nil { return nil, ErrEdgeNotFound } edgeReader := bytes.NewReader(edgeBytes) return deserializeChanEdgePolicy(edgeReader, nodes) } func fetchChanEdgePolicies(edgeIndex *bolt.Bucket, edges *bolt.Bucket, nodes *bolt.Bucket, chanID []byte, db *DB) (*ChannelEdgePolicy, *ChannelEdgePolicy, error) { edgeInfo := edgeIndex.Get(chanID) if edgeInfo == nil { return nil, nil, ErrEdgeNotFound } // The first node is contained within the first half of the edge // information. We only propagate the error here and below if it's // something other than edge non-existence. node1Pub := edgeInfo[:33] edge1, err := fetchChanEdgePolicy(edges, chanID, node1Pub, nodes) if err != nil && err != ErrEdgeNotFound { return nil, nil, err } // As we may have a single direction of the edge but not the other, // only fill in the database pointers if the edge is found. if edge1 != nil { edge1.db = db edge1.Node.db = db } // Similarly, the second node is contained within the latter // half of the edge information. node2Pub := edgeInfo[33:67] edge2, err := fetchChanEdgePolicy(edges, chanID, node2Pub, nodes) if err != nil && err != ErrEdgeNotFound { return nil, nil, err } if edge2 != nil { edge2.db = db edge2.Node.db = db } return edge1, edge2, nil } func deserializeChanEdgePolicy(r io.Reader, nodes *bolt.Bucket) (*ChannelEdgePolicy, error) { edge := &ChannelEdgePolicy{} sigBytes, err := wire.ReadVarBytes(r, 0, 80, "sig") if err != nil { return nil, err } edge.Signature, err = btcec.ParseSignature(sigBytes, btcec.S256()) if err != nil { return nil, err } if err := binary.Read(r, byteOrder, &edge.ChannelID); err != nil { return nil, err } var scratch [8]byte if _, err := r.Read(scratch[:]); err != nil { return nil, err } unix := int64(byteOrder.Uint64(scratch[:])) edge.LastUpdate = time.Unix(unix, 0) if err := binary.Read(r, byteOrder, &edge.Flags); err != nil { return nil, err } if err := binary.Read(r, byteOrder, &edge.TimeLockDelta); err != nil { return nil, err } var n uint64 if err := binary.Read(r, byteOrder, &n); err != nil { return nil, err } edge.MinHTLC = lnwire.MilliSatoshi(n) if err := binary.Read(r, byteOrder, &n); err != nil { return nil, err } edge.FeeBaseMSat = lnwire.MilliSatoshi(n) if err := binary.Read(r, byteOrder, &n); err != nil { return nil, err } edge.FeeProportionalMillionths = lnwire.MilliSatoshi(n) var pub [33]byte if _, err := r.Read(pub[:]); err != nil { return nil, err } node, err := fetchLightningNode(nodes, pub[:]) if err != nil { return nil, err } edge.Node = node return edge, nil }