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

 // Copyright 2014 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 cha computes the call graph of a Go program using the Class
 // Hierarchy Analysis (CHA) algorithm.
 //
 // CHA was first described in "Optimization of Object-Oriented Programs
 // Using Static Class Hierarchy Analysis", Jeffrey Dean, David Grove,
 // and Craig Chambers, ECOOP'95.
 //
 // CHA is related to RTA (see go/callgraph/rta); the difference is that
 // CHA conservatively computes the entire "implements" relation between
 // interfaces and concrete types ahead of time, whereas RTA uses dynamic
 // programming to construct it on the fly as it encounters new functions
 // reachable from main.  CHA may thus include spurious call edges for
 // types that haven't been instantiated yet, or types that are never
 // instantiated.
 //
 // Since CHA conservatively assumes that all functions are address-taken
 // and all concrete types are put into interfaces, it is sound to run on
 // partial programs, such as libraries without a main or test function.
 //
 package cha // import "golang.org/x/tools/go/callgraph/cha"

 import (
 	"go/types"

 	"golang.org/x/tools/go/callgraph"
 	"golang.org/x/tools/go/ssa"
 	"golang.org/x/tools/go/ssa/ssautil"
 	"golang.org/x/tools/go/types/typeutil"
 )

 // CallGraph computes the call graph of the specified program using the
 // Class Hierarchy Analysis algorithm.
 //
 func CallGraph(prog *ssa.Program) *callgraph.Graph {
 	cg := callgraph.New(nil) // TODO(adonovan) eliminate concept of rooted callgraph

 	allFuncs := ssautil.AllFunctions(prog)

 	// funcsBySig contains all functions, keyed by signature.  It is
 	// the effective set of address-taken functions used to resolve
 	// a dynamic call of a particular signature.
 	var funcsBySig typeutil.Map // value is []*ssa.Function

 	// methodsByName contains all methods,
 	// grouped by name for efficient lookup.
 	// (methodsById would be better but not every SSA method has a go/types ID.)
 	methodsByName := make(map[string][]*ssa.Function)

 	// An imethod represents an interface method I.m.
 	// (There's no go/types object for it;
 	// a *types.Func may be shared by many interfaces due to interface embedding.)
 	type imethod struct {
 		I  *types.Interface
 		id string
 	}
 	// methodsMemo records, for every abstract method call I.m on
 	// interface type I, the set of concrete methods C.m of all
 	// types C that satisfy interface I.
 	//
 	// Abstract methods may be shared by several interfaces,
 	// hence we must pass I explicitly, not guess from m.
 	//
 	// methodsMemo is just a cache, so it needn't be a typeutil.Map.
 	methodsMemo := make(map[imethod][]*ssa.Function)
 	lookupMethods := func(I *types.Interface, m *types.Func) []*ssa.Function {
 		id := m.Id()
 		methods, ok := methodsMemo[imethod{I, id}]
 		if !ok {
 			for _, f := range methodsByName[m.Name()] {
 				C := f.Signature.Recv().Type() // named or *named
 				if types.Implements(C, I) {
 					methods = append(methods, f)
 				}
 			}
 			methodsMemo[imethod{I, id}] = methods
 		}
 		return methods
 	}

 	for f := range allFuncs {
 		if f.Signature.Recv() == nil {
 			// Package initializers can never be address-taken.
 			if f.Name() == "init" && f.Synthetic == "package initializer" {
 				continue
 			}
 			funcs, _ := funcsBySig.At(f.Signature).([]*ssa.Function)
 			funcs = append(funcs, f)
 			funcsBySig.Set(f.Signature, funcs)
 		} else {
 			methodsByName[f.Name()] = append(methodsByName[f.Name()], f)
 		}
 	}

 	addEdge := func(fnode *callgraph.Node, site ssa.CallInstruction, g *ssa.Function) {
 		gnode := cg.CreateNode(g)
 		callgraph.AddEdge(fnode, site, gnode)
 	}

 	addEdges := func(fnode *callgraph.Node, site ssa.CallInstruction, callees []*ssa.Function) {
 		// Because every call to a highly polymorphic and
 		// frequently used abstract method such as
 		// (io.Writer).Write is assumed to call every concrete
 		// Write method in the program, the call graph can
 		// contain a lot of duplication.
 		//
 		// TODO(adonovan): opt: consider factoring the callgraph
 		// API so that the Callers component of each edge is a
 		// slice of nodes, not a singleton.
 		for _, g := range callees {
 			addEdge(fnode, site, g)
 		}
 	}

 	for f := range allFuncs {
 		fnode := cg.CreateNode(f)
 		for _, b := range f.Blocks {
 			for _, instr := range b.Instrs {
 				if site, ok := instr.(ssa.CallInstruction); ok {
 					call := site.Common()
 					if call.IsInvoke() {
 						tiface := call.Value.Type().Underlying().(*types.Interface)
 						addEdges(fnode, site, lookupMethods(tiface, call.Method))
 					} else if g := call.StaticCallee(); g != nil {
 						addEdge(fnode, site, g)
 					} else if _, ok := call.Value.(*ssa.Builtin); !ok {
 						callees, _ := funcsBySig.At(call.Signature()).([]*ssa.Function)
 						addEdges(fnode, site, callees)
 					}
 				}
 			}
 		}
 	}

 	return cg
 }
	// Copyright 2014 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 cha computes the call graph of a Go program using the Class
	// Hierarchy Analysis (CHA) algorithm.
	//
	// CHA was first described in "Optimization of Object-Oriented Programs
	// Using Static Class Hierarchy Analysis", Jeffrey Dean, David Grove,
	// and Craig Chambers, ECOOP'95.
	//
	// CHA is related to RTA (see go/callgraph/rta); the difference is that
	// CHA conservatively computes the entire "implements" relation between
	// interfaces and concrete types ahead of time, whereas RTA uses dynamic
	// programming to construct it on the fly as it encounters new functions
	// reachable from main. CHA may thus include spurious call edges for
	// types that haven't been instantiated yet, or types that are never
	// instantiated.
	//
	// Since CHA conservatively assumes that all functions are address-taken
	// and all concrete types are put into interfaces, it is sound to run on
	// partial programs, such as libraries without a main or test function.
	//
	package cha // import "golang.org/x/tools/go/callgraph/cha"

	import (
	"go/types"

	"golang.org/x/tools/go/callgraph"
	"golang.org/x/tools/go/ssa"
	"golang.org/x/tools/go/ssa/ssautil"
	"golang.org/x/tools/go/types/typeutil"
	)

	// CallGraph computes the call graph of the specified program using the
	// Class Hierarchy Analysis algorithm.
	//
	func CallGraph(prog ssa.Program) callgraph.Graph {
	cg := callgraph.New(nil) // TODO(adonovan) eliminate concept of rooted callgraph

	allFuncs := ssautil.AllFunctions(prog)

	// funcsBySig contains all functions, keyed by signature. It is
	// the effective set of address-taken functions used to resolve
	// a dynamic call of a particular signature.
	var funcsBySig typeutil.Map // value is []*ssa.Function

	// methodsByName contains all methods,
	// grouped by name for efficient lookup.
	// (methodsById would be better but not every SSA method has a go/types ID.)
	methodsByName := make(map[string][]*ssa.Function)

	// An imethod represents an interface method I.m.
	// (There's no go/types object for it;
	// a *types.Func may be shared by many interfaces due to interface embedding.)
	type imethod struct {
	I *types.Interface
	id string
	}
	// methodsMemo records, for every abstract method call I.m on
	// interface type I, the set of concrete methods C.m of all
	// types C that satisfy interface I.
	//
	// Abstract methods may be shared by several interfaces,
	// hence we must pass I explicitly, not guess from m.
	//
	// methodsMemo is just a cache, so it needn't be a typeutil.Map.
	methodsMemo := make(map[imethod][]*ssa.Function)
	lookupMethods := func(I types.Interface, m types.Func) []*ssa.Function {
	id := m.Id()
	methods, ok := methodsMemo[imethod{I, id}]
	if !ok {
	for _, f := range methodsByName[m.Name()] {
	C := f.Signature.Recv().Type() // named or *named
	if types.Implements(C, I) {
	methods = append(methods, f)
	}
	}
	methodsMemo[imethod{I, id}] = methods
	}
	return methods
	}

	for f := range allFuncs {
	if f.Signature.Recv() == nil {
	// Package initializers can never be address-taken.
	if f.Name() == "init" && f.Synthetic == "package initializer" {
	continue
	}
	funcs, _ := funcsBySig.At(f.Signature).([]*ssa.Function)
	funcs = append(funcs, f)
	funcsBySig.Set(f.Signature, funcs)
	} else {
	methodsByName[f.Name()] = append(methodsByName[f.Name()], f)
	}
	}

	addEdge := func(fnode callgraph.Node, site ssa.CallInstruction, g ssa.Function) {
	gnode := cg.CreateNode(g)
	callgraph.AddEdge(fnode, site, gnode)
	}

	addEdges := func(fnode callgraph.Node, site ssa.CallInstruction, callees []ssa.Function) {
	// Because every call to a highly polymorphic and
	// frequently used abstract method such as
	// (io.Writer).Write is assumed to call every concrete
	// Write method in the program, the call graph can
	// contain a lot of duplication.
	//
	// TODO(adonovan): opt: consider factoring the callgraph
	// API so that the Callers component of each edge is a
	// slice of nodes, not a singleton.
	for _, g := range callees {
	addEdge(fnode, site, g)
	}
	}

	for f := range allFuncs {
	fnode := cg.CreateNode(f)
	for _, b := range f.Blocks {
	for _, instr := range b.Instrs {
	if site, ok := instr.(ssa.CallInstruction); ok {
	call := site.Common()
	if call.IsInvoke() {
	tiface := call.Value.Type().Underlying().(*types.Interface)
	addEdges(fnode, site, lookupMethods(tiface, call.Method))
	} else if g := call.StaticCallee(); g != nil {
	addEdge(fnode, site, g)
	} else if _, ok := call.Value.(*ssa.Builtin); !ok {
	callees, _ := funcsBySig.At(call.Signature()).([]*ssa.Function)
	addEdges(fnode, site, callees)
	}
	}
	}
	}
	}

	return cg
	}