go/callgraph/callgraph.go - tools - Git at Google

 // Copyright 2013 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 /*

 Package callgraph defines the call graph and various algorithms
 and utilities to operate on it.

 A call graph is a labelled directed graph whose nodes represent
 functions and whose edge labels represent syntactic function call
 sites.  The presence of a labelled edge (caller, site, callee)
 indicates that caller may call callee at the specified call site.

 A call graph is a multigraph: it may contain multiple edges (caller,
 *, callee) connecting the same pair of nodes, so long as the edges
 differ by label; this occurs when one function calls another function
 from multiple call sites.  Also, it may contain multiple edges
 (caller, site, *) that differ only by callee; this indicates a
 polymorphic call.

 A SOUND call graph is one that overapproximates the dynamic calling
 behaviors of the program in all possible executions.  One call graph
 is more PRECISE than another if it is a smaller overapproximation of
 the dynamic behavior.

 All call graphs have a synthetic root node which is responsible for
 calling main() and init().

 Calls to built-in functions (e.g. panic, println) are not represented
 in the call graph; they are treated like built-in operators of the
 language.

 */
 package callgraph // import "golang.org/x/tools/go/callgraph"

 // TODO(adonovan): add a function to eliminate wrappers from the
 // callgraph, preserving topology.
 // More generally, we could eliminate "uninteresting" nodes such as
 // nodes from packages we don't care about.

 import (
 	"fmt"
 	"go/token"

 	"golang.org/x/tools/go/ssa"
 )

 // A Graph represents a call graph.
 //
 // A graph may contain nodes that are not reachable from the root.
 // If the call graph is sound, such nodes indicate unreachable
 // functions.
 //
 type Graph struct {
 	Root  *Node                   // the distinguished root node
 	Nodes map[*ssa.Function]*Node // all nodes by function
 }

 // New returns a new Graph with the specified root node.
 func New(root *ssa.Function) *Graph {
 	g := &Graph{Nodes: make(map[*ssa.Function]*Node)}
 	g.Root = g.CreateNode(root)
 	return g
 }

 // CreateNode returns the Node for fn, creating it if not present.
 func (g *Graph) CreateNode(fn *ssa.Function) *Node {
 	n, ok := g.Nodes[fn]
 	if !ok {
 		n = &Node{Func: fn, ID: len(g.Nodes)}
 		g.Nodes[fn] = n
 	}
 	return n
 }

 // A Node represents a node in a call graph.
 type Node struct {
 	Func *ssa.Function // the function this node represents
 	ID   int           // 0-based sequence number
 	In   []*Edge       // unordered set of incoming call edges (n.In[*].Callee == n)
 	Out  []*Edge       // unordered set of outgoing call edges (n.Out[*].Caller == n)
 }

 func (n *Node) String() string {
 	return fmt.Sprintf("n%d:%s", n.ID, n.Func)
 }

 // A Edge represents an edge in the call graph.
 //
 // Site is nil for edges originating in synthetic or intrinsic
 // functions, e.g. reflect.Call or the root of the call graph.
 type Edge struct {
 	Caller *Node
 	Site   ssa.CallInstruction
 	Callee *Node
 }

 func (e Edge) String() string {
 	return fmt.Sprintf("%s --> %s", e.Caller, e.Callee)
 }

 func (e Edge) Description() string {
 	var prefix string
 	switch e.Site.(type) {
 	case nil:
 		return "synthetic call"
 	case *ssa.Go:
 		prefix = "concurrent "
 	case *ssa.Defer:
 		prefix = "deferred "
 	}
 	return prefix + e.Site.Common().Description()
 }

 func (e Edge) Pos() token.Pos {
 	if e.Site == nil {
 		return token.NoPos
 	}
 	return e.Site.Pos()
 }

 // AddEdge adds the edge (caller, site, callee) to the call graph.
 // Elimination of duplicate edges is the caller's responsibility.
 func AddEdge(caller *Node, site ssa.CallInstruction, callee *Node) {
 	e := &Edge{caller, site, callee}
 	callee.In = append(callee.In, e)
 	caller.Out = append(caller.Out, e)
 }
	// Copyright 2013 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	/*

	Package callgraph defines the call graph and various algorithms
	and utilities to operate on it.

	A call graph is a labelled directed graph whose nodes represent
	functions and whose edge labels represent syntactic function call
	sites. The presence of a labelled edge (caller, site, callee)
	indicates that caller may call callee at the specified call site.

	A call graph is a multigraph: it may contain multiple edges (caller,
	*, callee) connecting the same pair of nodes, so long as the edges
	differ by label; this occurs when one function calls another function
	from multiple call sites. Also, it may contain multiple edges
	(caller, site, *) that differ only by callee; this indicates a
	polymorphic call.

	A SOUND call graph is one that overapproximates the dynamic calling
	behaviors of the program in all possible executions. One call graph
	is more PRECISE than another if it is a smaller overapproximation of
	the dynamic behavior.

	All call graphs have a synthetic root node which is responsible for
	calling main() and init().

	Calls to built-in functions (e.g. panic, println) are not represented
	in the call graph; they are treated like built-in operators of the
	language.

	*/
	package callgraph // import "golang.org/x/tools/go/callgraph"

	// TODO(adonovan): add a function to eliminate wrappers from the
	// callgraph, preserving topology.
	// More generally, we could eliminate "uninteresting" nodes such as
	// nodes from packages we don't care about.

	import (
	"fmt"
	"go/token"

	"golang.org/x/tools/go/ssa"
	)

	// A Graph represents a call graph.
	//
	// A graph may contain nodes that are not reachable from the root.
	// If the call graph is sound, such nodes indicate unreachable
	// functions.
	//
	type Graph struct {
	Root *Node // the distinguished root node
	Nodes map[ssa.Function]Node // all nodes by function
	}

	// New returns a new Graph with the specified root node.
	func New(root ssa.Function) Graph {
	g := &Graph{Nodes: make(map[ssa.Function]Node)}
	g.Root = g.CreateNode(root)
	return g
	}

	// CreateNode returns the Node for fn, creating it if not present.
	func (g Graph) CreateNode(fn ssa.Function) *Node {
	n, ok := g.Nodes[fn]
	if !ok {
	n = &Node{Func: fn, ID: len(g.Nodes)}
	g.Nodes[fn] = n
	}
	return n
	}

	// A Node represents a node in a call graph.
	type Node struct {
	Func *ssa.Function // the function this node represents
	ID int // 0-based sequence number
	In []Edge // unordered set of incoming call edges (n.In[].Callee == n)
	Out []Edge // unordered set of outgoing call edges (n.Out[].Caller == n)
	}

	func (n *Node) String() string {
	return fmt.Sprintf("n%d:%s", n.ID, n.Func)
	}

	// A Edge represents an edge in the call graph.
	//
	// Site is nil for edges originating in synthetic or intrinsic
	// functions, e.g. reflect.Call or the root of the call graph.
	type Edge struct {
	Caller *Node
	Site ssa.CallInstruction
	Callee *Node
	}

	func (e Edge) String() string {
	return fmt.Sprintf("%s --> %s", e.Caller, e.Callee)
	}

	func (e Edge) Description() string {
	var prefix string
	switch e.Site.(type) {
	case nil:
	return "synthetic call"
	case *ssa.Go:
	prefix = "concurrent "
	case *ssa.Defer:
	prefix = "deferred "
	}
	return prefix + e.Site.Common().Description()
	}

	func (e Edge) Pos() token.Pos {
	if e.Site == nil {
	return token.NoPos
	}
	return e.Site.Pos()
	}

	// AddEdge adds the edge (caller, site, callee) to the call graph.
	// Elimination of duplicate edges is the caller's responsibility.
	func AddEdge(caller Node, site ssa.CallInstruction, callee Node) {
	e := &Edge{caller, site, callee}
	callee.In = append(callee.In, e)
	caller.Out = append(caller.Out, e)
	}