github.com/pankona/gometalinter@v2.0.11+incompatible/_linters/src/golang.org/x/tools/go/callgraph/util.go (about) 1 // Copyright 2013 The Go Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 package callgraph 6 7 import "golang.org/x/tools/go/ssa" 8 9 // This file provides various utilities over call graphs, such as 10 // visitation and path search. 11 12 // CalleesOf returns a new set containing all direct callees of the 13 // caller node. 14 // 15 func CalleesOf(caller *Node) map[*Node]bool { 16 callees := make(map[*Node]bool) 17 for _, e := range caller.Out { 18 callees[e.Callee] = true 19 } 20 return callees 21 } 22 23 // GraphVisitEdges visits all the edges in graph g in depth-first order. 24 // The edge function is called for each edge in postorder. If it 25 // returns non-nil, visitation stops and GraphVisitEdges returns that 26 // value. 27 // 28 func GraphVisitEdges(g *Graph, edge func(*Edge) error) error { 29 seen := make(map[*Node]bool) 30 var visit func(n *Node) error 31 visit = func(n *Node) error { 32 if !seen[n] { 33 seen[n] = true 34 for _, e := range n.Out { 35 if err := visit(e.Callee); err != nil { 36 return err 37 } 38 if err := edge(e); err != nil { 39 return err 40 } 41 } 42 } 43 return nil 44 } 45 for _, n := range g.Nodes { 46 if err := visit(n); err != nil { 47 return err 48 } 49 } 50 return nil 51 } 52 53 // PathSearch finds an arbitrary path starting at node start and 54 // ending at some node for which isEnd() returns true. On success, 55 // PathSearch returns the path as an ordered list of edges; on 56 // failure, it returns nil. 57 // 58 func PathSearch(start *Node, isEnd func(*Node) bool) []*Edge { 59 stack := make([]*Edge, 0, 32) 60 seen := make(map[*Node]bool) 61 var search func(n *Node) []*Edge 62 search = func(n *Node) []*Edge { 63 if !seen[n] { 64 seen[n] = true 65 if isEnd(n) { 66 return stack 67 } 68 for _, e := range n.Out { 69 stack = append(stack, e) // push 70 if found := search(e.Callee); found != nil { 71 return found 72 } 73 stack = stack[:len(stack)-1] // pop 74 } 75 } 76 return nil 77 } 78 return search(start) 79 } 80 81 // DeleteSyntheticNodes removes from call graph g all nodes for 82 // synthetic functions (except g.Root and package initializers), 83 // preserving the topology. In effect, calls to synthetic wrappers 84 // are "inlined". 85 // 86 func (g *Graph) DeleteSyntheticNodes() { 87 // Measurements on the standard library and go.tools show that 88 // resulting graph has ~15% fewer nodes and 4-8% fewer edges 89 // than the input. 90 // 91 // Inlining a wrapper of in-degree m, out-degree n adds m*n 92 // and removes m+n edges. Since most wrappers are monomorphic 93 // (n=1) this results in a slight reduction. Polymorphic 94 // wrappers (n>1), e.g. from embedding an interface value 95 // inside a struct to satisfy some interface, cause an 96 // increase in the graph, but they seem to be uncommon. 97 98 // Hash all existing edges to avoid creating duplicates. 99 edges := make(map[Edge]bool) 100 for _, cgn := range g.Nodes { 101 for _, e := range cgn.Out { 102 edges[*e] = true 103 } 104 } 105 for fn, cgn := range g.Nodes { 106 if cgn == g.Root || fn.Synthetic == "" || isInit(cgn.Func) { 107 continue // keep 108 } 109 for _, eIn := range cgn.In { 110 for _, eOut := range cgn.Out { 111 newEdge := Edge{eIn.Caller, eIn.Site, eOut.Callee} 112 if edges[newEdge] { 113 continue // don't add duplicate 114 } 115 AddEdge(eIn.Caller, eIn.Site, eOut.Callee) 116 edges[newEdge] = true 117 } 118 } 119 g.DeleteNode(cgn) 120 } 121 } 122 123 func isInit(fn *ssa.Function) bool { 124 return fn.Pkg != nil && fn.Pkg.Func("init") == fn 125 } 126 127 // DeleteNode removes node n and its edges from the graph g. 128 // (NB: not efficient for batch deletion.) 129 func (g *Graph) DeleteNode(n *Node) { 130 n.deleteIns() 131 n.deleteOuts() 132 delete(g.Nodes, n.Func) 133 } 134 135 // deleteIns deletes all incoming edges to n. 136 func (n *Node) deleteIns() { 137 for _, e := range n.In { 138 removeOutEdge(e) 139 } 140 n.In = nil 141 } 142 143 // deleteOuts deletes all outgoing edges from n. 144 func (n *Node) deleteOuts() { 145 for _, e := range n.Out { 146 removeInEdge(e) 147 } 148 n.Out = nil 149 } 150 151 // removeOutEdge removes edge.Caller's outgoing edge 'edge'. 152 func removeOutEdge(edge *Edge) { 153 caller := edge.Caller 154 n := len(caller.Out) 155 for i, e := range caller.Out { 156 if e == edge { 157 // Replace it with the final element and shrink the slice. 158 caller.Out[i] = caller.Out[n-1] 159 caller.Out[n-1] = nil // aid GC 160 caller.Out = caller.Out[:n-1] 161 return 162 } 163 } 164 panic("edge not found: " + edge.String()) 165 } 166 167 // removeInEdge removes edge.Callee's incoming edge 'edge'. 168 func removeInEdge(edge *Edge) { 169 caller := edge.Callee 170 n := len(caller.In) 171 for i, e := range caller.In { 172 if e == edge { 173 // Replace it with the final element and shrink the slice. 174 caller.In[i] = caller.In[n-1] 175 caller.In[n-1] = nil // aid GC 176 caller.In = caller.In[:n-1] 177 return 178 } 179 } 180 panic("edge not found: " + edge.String()) 181 }