package main
import (
"errors"
"fmt"
"io"
"sort"
dot "github.com/kishansagathiya/go-dot"
peer "github.com/libp2p/go-libp2p-core/peer"
"github.com/ipfs-cluster/ipfs-cluster/api"
)
/*
These functions are used to write an IPFS Cluster connectivity graph to a
graphviz-style dot file. Input an api.ConnectGraphSerial object, makeDot
does some preprocessing and then passes all 3 link maps to a
cluster-dotWriter which handles iterating over the link maps and writing
dot file node and edge statements to make a dot-file graph. Nodes are
labeled with the go-libp2p-peer shortened peer id. IPFS nodes are rendered
with turquoise boundaries, Cluster nodes with orange. Currently preprocessing
consists of moving IPFS swarm peers not connected to any cluster peer to
the IPFSLinks map in the event that the function was invoked with the
allIpfs flag. This allows all IPFS peers connected to the cluster to be
rendered as nodes in the final graph.
*/
// nodeType specifies the type of node being represented in the dot file:
// either IPFS or Cluster
type nodeType int
const (
tSelfCluster nodeType = iota // cluster self node
tCluster // cluster node
tTrustedCluster // trusted cluster node
tIPFS // IPFS node
tIPFSMissing // Missing IPFS node
)
var errUnknownNodeType = errors.New("unsupported node type. Expected cluster or ipfs")
func makeDot(cg api.ConnectGraph, w io.Writer, allIpfs bool) error {
ipfsEdges := make(map[string][]peer.ID)
for k, v := range cg.IPFSLinks {
ipfsEdges[k] = make([]peer.ID, 0)
for _, id := range v {
strPid := peer.Encode(id)
if _, ok := cg.IPFSLinks[strPid]; ok || allIpfs {
ipfsEdges[k] = append(ipfsEdges[k], id)
}
if allIpfs { // include all swarm peers in the graph
if _, ok := ipfsEdges[strPid]; !ok {
// if id in IPFSLinks this will be overwritten
// if id not in IPFSLinks this will stay blank
ipfsEdges[strPid] = make([]peer.ID, 0)
}
}
}
}
dW := dotWriter{
w: w,
dotGraph: dot.NewGraph("cluster"),
self: peer.Encode(cg.ClusterID),
trustMap: cg.ClusterTrustLinks,
idToPeername: cg.IDtoPeername,
ipfsEdges: ipfsEdges,
clusterEdges: cg.ClusterLinks,
clusterIpfsEdges: cg.ClustertoIPFS,
clusterNodes: make(map[string]*dot.VertexDescription),
ipfsNodes: make(map[string]*dot.VertexDescription),
}
return dW.print()
}
type dotWriter struct {
clusterNodes map[string]*dot.VertexDescription
ipfsNodes map[string]*dot.VertexDescription
w io.Writer
dotGraph dot.Graph
self string
idToPeername map[string]string
trustMap map[string]bool
ipfsEdges map[string][]peer.ID
clusterEdges map[string][]peer.ID
clusterIpfsEdges map[string]peer.ID
}
func (dW *dotWriter) addSubGraph(sGraph dot.Graph, rank string) {
sGraph.IsSubGraph = true
sGraph.Rank = rank
dW.dotGraph.AddSubGraph(&sGraph)
}
// writes nodes to dot file output and creates and stores an ordering over nodes
func (dW *dotWriter) addNode(graph *dot.Graph, id string, nT nodeType) error {
node := dot.NewVertexDescription("")
node.Group = id
node.ColorScheme = "x11"
node.FontName = "Arial"
node.Style = "filled"
node.FontColor = "black"
switch nT {
case tSelfCluster:
node.ID = fmt.Sprintf("C%d", len(dW.clusterNodes))
node.Shape = "box3d"
node.Label = label(dW.idToPeername[id], shorten(id))
node.Color = "orange"
node.Peripheries = 2
dW.clusterNodes[id] = &node
case tTrustedCluster:
node.ID = fmt.Sprintf("T%d", len(dW.clusterNodes))
node.Shape = "box3d"
node.Label = label(dW.idToPeername[id], shorten(id))
node.Color = "orange"
dW.clusterNodes[id] = &node
case tCluster:
node.Shape = "box3d"
node.Label = label(dW.idToPeername[id], shorten(id))
node.ID = fmt.Sprintf("C%d", len(dW.clusterNodes))
node.Color = "darkorange3"
dW.clusterNodes[id] = &node
case tIPFS:
node.ID = fmt.Sprintf("I%d", len(dW.ipfsNodes))
node.Shape = "cylinder"
node.Label = label("IPFS", shorten(id))
node.Color = "turquoise3"
dW.ipfsNodes[id] = &node
case tIPFSMissing:
node.ID = fmt.Sprintf("I%d", len(dW.ipfsNodes))
node.Shape = "cylinder"
node.Label = label("IPFS", "Errored")
node.Color = "firebrick1"
dW.ipfsNodes[id] = &node
default:
return errUnknownNodeType
}
graph.AddVertex(&node)
return nil
}
func shorten(id string) string {
return id[:2] + "*" + id[len(id)-6:]
}
func label(peername, id string) string {
return fmt.Sprintf("< %s
%s >", peername, id)
}
func (dW *dotWriter) print() error {
dW.dotGraph.AddComment("The nodes of the connectivity graph")
dW.dotGraph.AddComment("The cluster-service peers")
// Write cluster nodes, use sorted order for consistent labels
sGraphCluster := dot.NewGraph("")
sGraphCluster.IsSubGraph = true
sortedClusterEdges := sortedKeys(dW.clusterEdges)
for _, k := range sortedClusterEdges {
var err error
if k == dW.self {
err = dW.addNode(&sGraphCluster, k, tSelfCluster)
} else if dW.trustMap[k] {
err = dW.addNode(&sGraphCluster, k, tTrustedCluster)
} else {
err = dW.addNode(&sGraphCluster, k, tCluster)
}
if err != nil {
return err
}
}
dW.addSubGraph(sGraphCluster, "min")
dW.dotGraph.AddNewLine()
dW.dotGraph.AddComment("The ipfs peers")
sGraphIPFS := dot.NewGraph("")
sGraphIPFS.IsSubGraph = true
// Write ipfs nodes, use sorted order for consistent labels
for _, k := range sortedKeys(dW.ipfsEdges) {
err := dW.addNode(&sGraphIPFS, k, tIPFS)
if err != nil {
return err
}
}
for _, k := range sortedClusterEdges {
if _, ok := dW.clusterIpfsEdges[k]; !ok {
err := dW.addNode(&sGraphIPFS, k, tIPFSMissing)
if err != nil {
return err
}
}
}
dW.addSubGraph(sGraphIPFS, "max")
dW.dotGraph.AddNewLine()
dW.dotGraph.AddComment("Edges representing active connections in the cluster")
dW.dotGraph.AddComment("The connections among cluster-service peers")
// Write cluster edges
for _, k := range sortedClusterEdges {
v := dW.clusterEdges[k]
for _, id := range v {
toNode := dW.clusterNodes[k]
fromNode := dW.clusterNodes[peer.Encode(id)]
dW.dotGraph.AddEdge(toNode, fromNode, true, "")
}
}
dW.dotGraph.AddNewLine()
dW.dotGraph.AddComment("The connections between cluster peers and their ipfs daemons")
// Write cluster to ipfs edges
for _, k := range sortedClusterEdges {
var fromNode *dot.VertexDescription
toNode := dW.clusterNodes[k]
ipfsID, ok := dW.clusterIpfsEdges[k]
if !ok {
fromNode, ok2 := dW.ipfsNodes[k]
if !ok2 {
logger.Error("expected a node at this id")
continue
}
dW.dotGraph.AddEdge(toNode, fromNode, true, "dotted")
continue
}
fromNode, ok = dW.ipfsNodes[peer.Encode(ipfsID)]
if !ok {
logger.Error("expected a node at this id")
continue
}
dW.dotGraph.AddEdge(toNode, fromNode, true, "")
}
dW.dotGraph.AddNewLine()
dW.dotGraph.AddComment("The swarm peer connections among ipfs daemons in the cluster")
// Write ipfs edges
for _, k := range sortedKeys(dW.ipfsEdges) {
v := dW.ipfsEdges[k]
toNode := dW.ipfsNodes[k]
for _, id := range v {
idStr := peer.Encode(id)
fromNode, ok := dW.ipfsNodes[idStr]
if !ok {
logger.Error("expected a node here")
continue
}
dW.dotGraph.AddEdge(toNode, fromNode, true, "")
}
}
return dW.dotGraph.Write(dW.w)
}
func sortedKeys(dict map[string][]peer.ID) []string {
keys := make([]string, len(dict))
i := 0
for k := range dict {
keys[i] = k
i++
}
sort.Strings(keys)
return keys
}