15838907453

Committed 24 Jun 2025 01:26AM UTC coverage: 57.079% (-11.1%) from 68.172%

Build # 15838907453

Build Type

Pull #9982

github

Committed by

web-flow

Commit Message

Merge e42780be2 into 45c15646c

Pull Request Pull Request #9982: lnwire+lnwallet: add LocalNonces field for splice nonce coordination w/ taproot channels

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103 of 167 new or added lines in 5 files covered. (61.68%)

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86.61

/graph/db/graph_cache.go

package graphdb

import (
        "fmt"
        "sync"

        "github.com/btcsuite/btcd/btcutil"
        "github.com/lightningnetwork/lnd/graph/db/models"
        "github.com/lightningnetwork/lnd/lnwire"
        "github.com/lightningnetwork/lnd/routing/route"
)

// DirectedChannel is a type that stores the channel information as seen from
// one side of the channel.
type DirectedChannel struct {
        // ChannelID is the unique identifier of this channel.
        ChannelID uint64

        // IsNode1 indicates if this is the node with the smaller public key.
        IsNode1 bool

        // OtherNode is the public key of the node on the other end of this
        // channel.
        OtherNode route.Vertex

        // Capacity is the announced capacity of this channel in satoshis.
        Capacity btcutil.Amount

        // OutPolicySet is a boolean that indicates whether the node has an
        // outgoing policy set. For pathfinding only the existence of the policy
        // is important to know, not the actual content.
        OutPolicySet bool

        // InPolicy is the incoming policy *from* the other node to this node.
        // In path finding, we're walking backward from the destination to the
        // source, so we're always interested in the edge that arrives to us
        // from the other node.
        InPolicy *models.CachedEdgePolicy

        // Inbound fees of this node.
        InboundFee lnwire.Fee
}

// DeepCopy creates a deep copy of the channel, including the incoming policy.
func (c *DirectedChannel) DeepCopy() *DirectedChannel {
        channelCopy := *c

        if channelCopy.InPolicy != nil {
                inPolicyCopy := *channelCopy.InPolicy
                channelCopy.InPolicy = &inPolicyCopy

                // The fields for the ToNode can be overwritten by the path
                // finding algorithm, which is why we need a deep copy in the
                // first place. So we always start out with nil values, just to
                // be sure they don't contain any old data.
                channelCopy.InPolicy.ToNodePubKey = nil
                channelCopy.InPolicy.ToNodeFeatures = nil
        }

        return &channelCopy
}

// GraphCache is a type that holds a minimal set of information of the public
// channel graph that can be used for pathfinding.
type GraphCache struct {
        nodeChannels map[route.Vertex]map[uint64]*DirectedChannel
        nodeFeatures map[route.Vertex]*lnwire.FeatureVector

        mtx sync.RWMutex
}

// NewGraphCache creates a new graphCache.
func NewGraphCache(preAllocNumNodes int) *GraphCache {
        return &GraphCache{
                nodeChannels: make(
                        map[route.Vertex]map[uint64]*DirectedChannel,
                        // A channel connects two nodes, so we can look it up
                        // from both sides, meaning we get double the number of
                        // entries.
                        preAllocNumNodes*2,
                ),
                nodeFeatures: make(
                        map[route.Vertex]*lnwire.FeatureVector,
                        preAllocNumNodes,
                ),
        }
}

// Stats returns statistics about the current cache size.
func (c *GraphCache) Stats() string {
        c.mtx.RLock()
        defer c.mtx.RUnlock()

        numChannels := 0
        for node := range c.nodeChannels {
                numChannels += len(c.nodeChannels[node])
        }
        return fmt.Sprintf("num_node_features=%d, num_nodes=%d, "+
                "num_channels=%d", len(c.nodeFeatures), len(c.nodeChannels),
                numChannels)
}

// AddNodeFeatures adds a graph node and its features to the cache.
func (c *GraphCache) AddNodeFeatures(node route.Vertex,
        features *lnwire.FeatureVector) {

        c.mtx.Lock()
        defer c.mtx.Unlock()

        c.nodeFeatures[node] = features
}

// AddChannel adds a non-directed channel, meaning that the order of policy 1
// and policy 2 does not matter, the directionality is extracted from the info
// and policy flags automatically. The policy will be set as the outgoing policy
// on one node and the incoming policy on the peer's side.
func (c *GraphCache) AddChannel(info *models.CachedEdgeInfo,
        policy1, policy2 *models.CachedEdgePolicy) {

        if info == nil {
                return
        }

        if policy1 != nil && policy1.IsDisabled() &&
                policy2 != nil && policy2.IsDisabled() {

                return
        }

        // Create the edge entry for both nodes.
        c.mtx.Lock()
        c.updateOrAddEdge(info.NodeKey1Bytes, &DirectedChannel{
                ChannelID: info.ChannelID,
                IsNode1:   true,
                OtherNode: info.NodeKey2Bytes,
                Capacity:  info.Capacity,
        })
        c.updateOrAddEdge(info.NodeKey2Bytes, &DirectedChannel{
                ChannelID: info.ChannelID,
                IsNode1:   false,
                OtherNode: info.NodeKey1Bytes,
                Capacity:  info.Capacity,
        })
        c.mtx.Unlock()

        // The policy's node is always the to_node. So if policy 1 has to_node
        // of node 2 then we have the policy 1 as seen from node 1.
        if policy1 != nil {
                fromNode, toNode := info.NodeKey1Bytes, info.NodeKey2Bytes
                if !policy1.IsNode1() {
                        fromNode, toNode = toNode, fromNode
                }
                c.UpdatePolicy(policy1, fromNode, toNode)
        }
        if policy2 != nil {
                fromNode, toNode := info.NodeKey2Bytes, info.NodeKey1Bytes
                if policy2.IsNode1() {
                        fromNode, toNode = toNode, fromNode
                }
                c.UpdatePolicy(policy2, fromNode, toNode)
        }
}

// updateOrAddEdge makes sure the edge information for a node is either updated
// if it already exists or is added to that node's list of channels.
func (c *GraphCache) updateOrAddEdge(node route.Vertex, edge *DirectedChannel) {
        if len(c.nodeChannels[node]) == 0 {
                c.nodeChannels[node] = make(map[uint64]*DirectedChannel)
        }

        c.nodeChannels[node][edge.ChannelID] = edge
}

// UpdatePolicy updates a single policy on both the from and to node. The order
// of the from and to node is not strictly important. But we assume that a
// channel edge was added beforehand so that the directed channel struct already
// exists in the cache.
func (c *GraphCache) UpdatePolicy(policy *models.CachedEdgePolicy, fromNode,
        toNode route.Vertex) {

        c.mtx.Lock()
        defer c.mtx.Unlock()

        updatePolicy := func(nodeKey route.Vertex) {
                if len(c.nodeChannels[nodeKey]) == 0 {
                        log.Warnf("Node=%v not found in graph cache", nodeKey)

                        return
                }

                channel, ok := c.nodeChannels[nodeKey][policy.ChannelID]
                if !ok {
                        log.Warnf("Channel=%v not found in graph cache",
                                policy.ChannelID)

                        return
                }

                // Edge 1 is defined as the policy for the direction of node1 to
                // node2.
                switch {
                // This is node 1, and it is edge 1, so this is the outgoing
                // policy for node 1.
                case channel.IsNode1 && policy.IsNode1():
                        channel.OutPolicySet = true
                        policy.InboundFee.WhenSome(func(fee lnwire.Fee) {
                                channel.InboundFee = fee
                        })

                // This is node 2, and it is edge 2, so this is the outgoing
                // policy for node 2.
                case !channel.IsNode1 && !policy.IsNode1():
                        channel.OutPolicySet = true
                        policy.InboundFee.WhenSome(func(fee lnwire.Fee) {
                                channel.InboundFee = fee
                        })

                // The other two cases left mean it's the inbound policy for the
                // node.
                default:
                        channel.InPolicy = policy
                }
        }

        updatePolicy(fromNode)
        updatePolicy(toNode)
}

// RemoveNode completely removes a node and all its channels (including the
// peer's side).
func (c *GraphCache) RemoveNode(node route.Vertex) {
        c.mtx.Lock()
        defer c.mtx.Unlock()

        delete(c.nodeFeatures, node)

        // First remove all channels from the other nodes' lists.
        for _, channel := range c.nodeChannels[node] {
                c.removeChannelIfFound(channel.OtherNode, channel.ChannelID)
        }

        // Then remove our whole node completely.
        delete(c.nodeChannels, node)
}

// RemoveChannel removes a single channel between two nodes.
func (c *GraphCache) RemoveChannel(node1, node2 route.Vertex, chanID uint64) {
        c.mtx.Lock()
        defer c.mtx.Unlock()

        // Remove that one channel from both sides.
        c.removeChannelIfFound(node1, chanID)
        c.removeChannelIfFound(node2, chanID)
}

// removeChannelIfFound removes a single channel from one side.
func (c *GraphCache) removeChannelIfFound(node route.Vertex, chanID uint64) {
        if len(c.nodeChannels[node]) == 0 {
                return
        }

        delete(c.nodeChannels[node], chanID)
}

// getChannels returns a copy of the passed node's channels or nil if there
// isn't any.
func (c *GraphCache) getChannels(node route.Vertex) []*DirectedChannel {
        c.mtx.RLock()
        defer c.mtx.RUnlock()

        channels, ok := c.nodeChannels[node]
        if !ok {
                return nil
        }

        features, ok := c.nodeFeatures[node]
        if !ok {
                // If the features were set to nil explicitly, that's fine here.
                // The router will overwrite the features of the destination
                // node with those found in the invoice if necessary. But if we
                // didn't yet get a node announcement we want to mimic the
                // behavior of the old DB based code that would always set an
                // empty feature vector instead of leaving it nil.
                features = lnwire.EmptyFeatureVector()
        }

        toNodeCallback := func() route.Vertex {
                return node
        }

        i := 0
        channelsCopy := make([]*DirectedChannel, len(channels))
        for _, channel := range channels {
                // We need to copy the channel and policy to avoid it being
                // updated in the cache if the path finding algorithm sets
                // fields on it (currently only the ToNodeFeatures of the
                // policy).
                channelCopy := channel.DeepCopy()
                if channelCopy.InPolicy != nil {
                        channelCopy.InPolicy.ToNodePubKey = toNodeCallback
                        channelCopy.InPolicy.ToNodeFeatures = features
                }

                channelsCopy[i] = channelCopy
                i++
        }

        return channelsCopy
}

// ForEachChannel invokes the given callback for each channel of the given node.
func (c *GraphCache) ForEachChannel(node route.Vertex,
        cb func(channel *DirectedChannel) error) error {

        // Obtain a copy of the node's channels. We need do this in order to
        // avoid deadlocks caused by interaction with the graph cache, channel
        // state and the graph database from multiple goroutines. This snapshot
        // is only used for path finding where being stale is acceptable since
        // the real world graph and our representation may always become
        // slightly out of sync for a short time and the actual channel state
        // is stored separately.
        channels := c.getChannels(node)
        for _, channel := range channels {
                if err := cb(channel); err != nil {
                        return err
                }
        }

        return nil
}

// ForEachNode iterates over the adjacency list of the graph, executing the
// call back for each node and the set of channels that emanate from the given
// node.
//
// NOTE: This method should be considered _read only_, the channels or nodes
// passed in MUST NOT be modified.
func (c *GraphCache) ForEachNode(cb func(node route.Vertex,
        channels map[uint64]*DirectedChannel) error) error {

        c.mtx.RLock()
        defer c.mtx.RUnlock()

        for node, channels := range c.nodeChannels {
                // We don't make a copy here since this is a read-only RPC
                // call. We also don't need the node features either for this
                // call.
                if err := cb(node, channels); err != nil {
                        return err
                }
        }

        return nil
}

// GetFeatures returns the features of the node with the given ID. If no
// features are known for the node, an empty feature vector is returned.
func (c *GraphCache) GetFeatures(node route.Vertex) *lnwire.FeatureVector {
        c.mtx.RLock()
        defer c.mtx.RUnlock()

        features, ok := c.nodeFeatures[node]
        if !ok || features == nil {
                // The router expects the features to never be nil, so we return
                // an empty feature set instead.
                return lnwire.EmptyFeatureVector()
        }

        return features
}

1	package graphdb
2
3	import (
4	"fmt"
5	"sync"
6
7	"github.com/btcsuite/btcd/btcutil"
8	"github.com/lightningnetwork/lnd/graph/db/models"
9	"github.com/lightningnetwork/lnd/lnwire"
10	"github.com/lightningnetwork/lnd/routing/route"
11	)
12
13	// DirectedChannel is a type that stores the channel information as seen from
14	// one side of the channel.
15	type DirectedChannel struct {
16	// ChannelID is the unique identifier of this channel.
17	ChannelID uint64
18
19	// IsNode1 indicates if this is the node with the smaller public key.
20	IsNode1 bool
21
22	// OtherNode is the public key of the node on the other end of this
23	// channel.
24	OtherNode route.Vertex
25
26	// Capacity is the announced capacity of this channel in satoshis.
27	Capacity btcutil.Amount
28
29	// OutPolicySet is a boolean that indicates whether the node has an
30	// outgoing policy set. For pathfinding only the existence of the policy
31	// is important to know, not the actual content.
32	OutPolicySet bool
33
34	// InPolicy is the incoming policy from the other node to this node.
35	// In path finding, we're walking backward from the destination to the
36	// source, so we're always interested in the edge that arrives to us
37	// from the other node.
38	InPolicy *models.CachedEdgePolicy
39
40	// Inbound fees of this node.
41	InboundFee lnwire.Fee
42	}
43
44	// DeepCopy creates a deep copy of the channel, including the incoming policy.
45	func (c DirectedChannel) DeepCopy() DirectedChannel {	1✔
46	channelCopy := *c	1✔
47		1✔
48	if channelCopy.InPolicy != nil {	2✔
49	inPolicyCopy := *channelCopy.InPolicy	1✔
50	channelCopy.InPolicy = &inPolicyCopy	1✔
51		1✔
52	// The fields for the ToNode can be overwritten by the path	1✔
53	// finding algorithm, which is why we need a deep copy in the	1✔
54	// first place. So we always start out with nil values, just to	1✔
55	// be sure they don't contain any old data.	1✔
56	channelCopy.InPolicy.ToNodePubKey = nil	1✔
57	channelCopy.InPolicy.ToNodeFeatures = nil	1✔
58	}	1✔
59
60	return &channelCopy	1✔
61	}
62
63	// GraphCache is a type that holds a minimal set of information of the public
64	// channel graph that can be used for pathfinding.
65	type GraphCache struct {
66	nodeChannels map[route.Vertex]map[uint64]*DirectedChannel
67	nodeFeatures map[route.Vertex]*lnwire.FeatureVector
68
69	mtx sync.RWMutex
70	}
71
72	// NewGraphCache creates a new graphCache.
73	func NewGraphCache(preAllocNumNodes int) *GraphCache {	1✔
74	return &GraphCache{	1✔
75	nodeChannels: make(	1✔
76	map[route.Vertex]map[uint64]*DirectedChannel,	1✔
77	// A channel connects two nodes, so we can look it up	1✔
78	// from both sides, meaning we get double the number of	1✔
79	// entries.	1✔
80	preAllocNumNodes*2,	1✔
81	),	1✔
82	nodeFeatures: make(	1✔
83	map[route.Vertex]*lnwire.FeatureVector,	1✔
84	preAllocNumNodes,	1✔
85	),	1✔
86	}	1✔
87	}	1✔
88
89	// Stats returns statistics about the current cache size.
90	func (c *GraphCache) Stats() string {	1✔
91	c.mtx.RLock()	1✔
92	defer c.mtx.RUnlock()	1✔
93		1✔
94	numChannels := 0	1✔
95	for node := range c.nodeChannels {	2✔
96	numChannels += len(c.nodeChannels[node])	1✔
97	}	1✔
98	return fmt.Sprintf("num_node_features=%d, num_nodes=%d, "+	1✔
99	"num_channels=%d", len(c.nodeFeatures), len(c.nodeChannels),	1✔
100	numChannels)	1✔
101	}
102
103	// AddNodeFeatures adds a graph node and its features to the cache.
104	func (c *GraphCache) AddNodeFeatures(node route.Vertex,
105	features *lnwire.FeatureVector) {	1✔
106		1✔
107	c.mtx.Lock()	1✔
108	defer c.mtx.Unlock()	1✔
109		1✔
110	c.nodeFeatures[node] = features	1✔
111	}	1✔
112
113	// AddChannel adds a non-directed channel, meaning that the order of policy 1
114	// and policy 2 does not matter, the directionality is extracted from the info
115	// and policy flags automatically. The policy will be set as the outgoing policy
116	// on one node and the incoming policy on the peer's side.
117	func (c GraphCache) AddChannel(info models.CachedEdgeInfo,
118	policy1, policy2 *models.CachedEdgePolicy) {	1✔
119		1✔
120	if info == nil {	1✔
121	return	×
122	}	×
123
124	if policy1 != nil && policy1.IsDisabled() &&	1✔
125	policy2 != nil && policy2.IsDisabled() {	2✔
126		1✔
127	return	1✔
128	}	1✔
129
130	// Create the edge entry for both nodes.
131	c.mtx.Lock()	1✔
132	c.updateOrAddEdge(info.NodeKey1Bytes, &DirectedChannel{	1✔
133	ChannelID: info.ChannelID,	1✔
134	IsNode1: true,	1✔
135	OtherNode: info.NodeKey2Bytes,	1✔
136	Capacity: info.Capacity,	1✔
137	})	1✔
138	c.updateOrAddEdge(info.NodeKey2Bytes, &DirectedChannel{	1✔
139	ChannelID: info.ChannelID,	1✔
140	IsNode1: false,	1✔
141	OtherNode: info.NodeKey1Bytes,	1✔
142	Capacity: info.Capacity,	1✔
143	})	1✔
144	c.mtx.Unlock()	1✔
145		1✔
146	// The policy's node is always the to_node. So if policy 1 has to_node	1✔
147	// of node 2 then we have the policy 1 as seen from node 1.	1✔
148	if policy1 != nil {	2✔
149	fromNode, toNode := info.NodeKey1Bytes, info.NodeKey2Bytes	1✔
150	if !policy1.IsNode1() {	1✔
UNCOV 151	fromNode, toNode = toNode, fromNode	×
UNCOV 152	}	×
153	c.UpdatePolicy(policy1, fromNode, toNode)	1✔
154	}
155	if policy2 != nil {	2✔
156	fromNode, toNode := info.NodeKey2Bytes, info.NodeKey1Bytes	1✔
157	if policy2.IsNode1() {	1✔
UNCOV 158	fromNode, toNode = toNode, fromNode	×
UNCOV 159	}	×
160	c.UpdatePolicy(policy2, fromNode, toNode)	1✔
161	}
162	}
163
164	// updateOrAddEdge makes sure the edge information for a node is either updated
165	// if it already exists or is added to that node's list of channels.
166	func (c GraphCache) updateOrAddEdge(node route.Vertex, edge DirectedChannel) {	1✔
167	if len(c.nodeChannels[node]) == 0 {	2✔
168	c.nodeChannels[node] = make(map[uint64]*DirectedChannel)	1✔
169	}	1✔
170
171	c.nodeChannels[node][edge.ChannelID] = edge	1✔
172	}
173
174	// UpdatePolicy updates a single policy on both the from and to node. The order
175	// of the from and to node is not strictly important. But we assume that a
176	// channel edge was added beforehand so that the directed channel struct already
177	// exists in the cache.
178	func (c GraphCache) UpdatePolicy(policy models.CachedEdgePolicy, fromNode,
179	toNode route.Vertex) {	1✔
180		1✔
181	c.mtx.Lock()	1✔
182	defer c.mtx.Unlock()	1✔
183		1✔
184	updatePolicy := func(nodeKey route.Vertex) {	2✔
185	if len(c.nodeChannels[nodeKey]) == 0 {	1✔
186	log.Warnf("Node=%v not found in graph cache", nodeKey)	×
187		×
188	return	×
189	}	×
190
191	channel, ok := c.nodeChannels[nodeKey][policy.ChannelID]	1✔
192	if !ok {	1✔
193	log.Warnf("Channel=%v not found in graph cache",	×
194	policy.ChannelID)	×
195		×
196	return	×
197	}	×
198
199	// Edge 1 is defined as the policy for the direction of node1 to
200	// node2.
201	switch {	1✔
202	// This is node 1, and it is edge 1, so this is the outgoing
203	// policy for node 1.
204	case channel.IsNode1 && policy.IsNode1():	1✔
205	channel.OutPolicySet = true	1✔
206	policy.InboundFee.WhenSome(func(fee lnwire.Fee) {	2✔
207	channel.InboundFee = fee	1✔
208	})	1✔
209
210	// This is node 2, and it is edge 2, so this is the outgoing
211	// policy for node 2.
212	case !channel.IsNode1 && !policy.IsNode1():	1✔
213	channel.OutPolicySet = true	1✔
214	policy.InboundFee.WhenSome(func(fee lnwire.Fee) {	2✔
215	channel.InboundFee = fee	1✔
216	})	1✔
217
218	// The other two cases left mean it's the inbound policy for the
219	// node.
220	default:	1✔
221	channel.InPolicy = policy	1✔
222	}
223	}
224
225	updatePolicy(fromNode)	1✔
226	updatePolicy(toNode)	1✔
227	}
228
229	// RemoveNode completely removes a node and all its channels (including the
230	// peer's side).
231	func (c *GraphCache) RemoveNode(node route.Vertex) {	1✔
232	c.mtx.Lock()	1✔
233	defer c.mtx.Unlock()	1✔
234		1✔
235	delete(c.nodeFeatures, node)	1✔
236		1✔
237	// First remove all channels from the other nodes' lists.	1✔
238	for _, channel := range c.nodeChannels[node] {	1✔
UNCOV 239	c.removeChannelIfFound(channel.OtherNode, channel.ChannelID)	×
UNCOV 240	}	×
241
242	// Then remove our whole node completely.
243	delete(c.nodeChannels, node)	1✔
244	}
245
246	// RemoveChannel removes a single channel between two nodes.
247	func (c *GraphCache) RemoveChannel(node1, node2 route.Vertex, chanID uint64) {	1✔
248	c.mtx.Lock()	1✔
249	defer c.mtx.Unlock()	1✔
250		1✔
251	// Remove that one channel from both sides.	1✔
252	c.removeChannelIfFound(node1, chanID)	1✔
253	c.removeChannelIfFound(node2, chanID)	1✔
254	}	1✔
255
256	// removeChannelIfFound removes a single channel from one side.
257	func (c *GraphCache) removeChannelIfFound(node route.Vertex, chanID uint64) {	1✔
258	if len(c.nodeChannels[node]) == 0 {	2✔
259	return	1✔
260	}	1✔
261
262	delete(c.nodeChannels[node], chanID)	1✔
263	}
264
265	// getChannels returns a copy of the passed node's channels or nil if there
266	// isn't any.
267	func (c GraphCache) getChannels(node route.Vertex) []DirectedChannel {	1✔
268	c.mtx.RLock()	1✔
269	defer c.mtx.RUnlock()	1✔
270		1✔
271	channels, ok := c.nodeChannels[node]	1✔
272	if !ok {	2✔
273	return nil	1✔
274	}	1✔
275
276	features, ok := c.nodeFeatures[node]	1✔
277	if !ok {	2✔
278	// If the features were set to nil explicitly, that's fine here.	1✔
279	// The router will overwrite the features of the destination	1✔
280	// node with those found in the invoice if necessary. But if we	1✔
281	// didn't yet get a node announcement we want to mimic the	1✔
282	// behavior of the old DB based code that would always set an	1✔
283	// empty feature vector instead of leaving it nil.	1✔
284	features = lnwire.EmptyFeatureVector()	1✔
285	}	1✔
286
287	toNodeCallback := func() route.Vertex {	2✔
288	return node	1✔
289	}	1✔
290
291	i := 0	1✔
292	channelsCopy := make([]*DirectedChannel, len(channels))	1✔
293	for _, channel := range channels {	2✔
294	// We need to copy the channel and policy to avoid it being	1✔
295	// updated in the cache if the path finding algorithm sets	1✔
296	// fields on it (currently only the ToNodeFeatures of the	1✔
297	// policy).	1✔
298	channelCopy := channel.DeepCopy()	1✔
299	if channelCopy.InPolicy != nil {	2✔
300	channelCopy.InPolicy.ToNodePubKey = toNodeCallback	1✔
301	channelCopy.InPolicy.ToNodeFeatures = features	1✔
302	}	1✔
303
304	channelsCopy[i] = channelCopy	1✔
305	i++	1✔
306	}
307
308	return channelsCopy	1✔
309	}
310
311	// ForEachChannel invokes the given callback for each channel of the given node.
312	func (c *GraphCache) ForEachChannel(node route.Vertex,
313	cb func(channel *DirectedChannel) error) error {	1✔
314		1✔
315	// Obtain a copy of the node's channels. We need do this in order to	1✔
316	// avoid deadlocks caused by interaction with the graph cache, channel	1✔
317	// state and the graph database from multiple goroutines. This snapshot	1✔
318	// is only used for path finding where being stale is acceptable since	1✔
319	// the real world graph and our representation may always become	1✔
320	// slightly out of sync for a short time and the actual channel state	1✔
321	// is stored separately.	1✔
322	channels := c.getChannels(node)	1✔
323	for _, channel := range channels {	2✔
324	if err := cb(channel); err != nil {	2✔
325	return err	1✔
326	}	1✔
327	}
328
329	return nil	1✔
330	}
331
332	// ForEachNode iterates over the adjacency list of the graph, executing the
333	// call back for each node and the set of channels that emanate from the given
334	// node.
335	//
336	// NOTE: This method should be considered _read only_, the channels or nodes
337	// passed in MUST NOT be modified.
338	func (c *GraphCache) ForEachNode(cb func(node route.Vertex,
UNCOV 339	channels map[uint64]*DirectedChannel) error) error {	×
UNCOV 340		×
UNCOV 341	c.mtx.RLock()	×
UNCOV 342	defer c.mtx.RUnlock()	×
UNCOV 343		×
UNCOV 344	for node, channels := range c.nodeChannels {	×
UNCOV 345	// We don't make a copy here since this is a read-only RPC	×
UNCOV 346	// call. We also don't need the node features either for this	×
UNCOV 347	// call.	×
UNCOV 348	if err := cb(node, channels); err != nil {	×
349	return err	×
350	}	×
351	}
352
UNCOV 353	return nil	×
354	}
355
356	// GetFeatures returns the features of the node with the given ID. If no
357	// features are known for the node, an empty feature vector is returned.
358	func (c GraphCache) GetFeatures(node route.Vertex) lnwire.FeatureVector {	1✔
359	c.mtx.RLock()	1✔
360	defer c.mtx.RUnlock()	1✔
361		1✔
362	features, ok := c.nodeFeatures[node]	1✔
363	if !ok \|\| features == nil {	2✔
364	// The router expects the features to never be nil, so we return	1✔
365	// an empty feature set instead.	1✔
366	return lnwire.EmptyFeatureVector()	1✔
367	}	1✔
368
369	return features	1✔
370	}

lightningnetwork / lnd / 15838907453

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