src/cmd/vet/deadcode.go - go - 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.

 // Check for syntactically unreachable code.

 package main

 import (
 	"go/ast"
 	"go/token"
 )

 func init() {
 	register("unreachable",
 		"check for unreachable code",
 		checkUnreachable,
 		funcDecl, funcLit)
 }

 type deadState struct {
 	f           *File
 	hasBreak    map[ast.Stmt]bool
 	hasGoto     map[string]bool
 	labels      map[string]ast.Stmt
 	breakTarget ast.Stmt

 	reachable bool
 }

 // checkUnreachable checks a function body for dead code.
 //
 // TODO(adonovan): use the new cfg package, which is more precise.
 func checkUnreachable(f *File, node ast.Node) {
 	var body *ast.BlockStmt
 	switch n := node.(type) {
 	case *ast.FuncDecl:
 		body = n.Body
 	case *ast.FuncLit:
 		body = n.Body
 	}
 	if body == nil {
 		return
 	}

 	d := &deadState{
 		f:        f,
 		hasBreak: make(map[ast.Stmt]bool),
 		hasGoto:  make(map[string]bool),
 		labels:   make(map[string]ast.Stmt),
 	}

 	d.findLabels(body)

 	d.reachable = true
 	d.findDead(body)
 }

 // findLabels gathers information about the labels defined and used by stmt
 // and about which statements break, whether a label is involved or not.
 func (d *deadState) findLabels(stmt ast.Stmt) {
 	switch x := stmt.(type) {
 	default:
 		d.f.Warnf(x.Pos(), "internal error in findLabels: unexpected statement %T", x)

 	case *ast.AssignStmt,
 		*ast.BadStmt,
 		*ast.DeclStmt,
 		*ast.DeferStmt,
 		*ast.EmptyStmt,
 		*ast.ExprStmt,
 		*ast.GoStmt,
 		*ast.IncDecStmt,
 		*ast.ReturnStmt,
 		*ast.SendStmt:
 		// no statements inside

 	case *ast.BlockStmt:
 		for _, stmt := range x.List {
 			d.findLabels(stmt)
 		}

 	case *ast.BranchStmt:
 		switch x.Tok {
 		case token.GOTO:
 			if x.Label != nil {
 				d.hasGoto[x.Label.Name] = true
 			}

 		case token.BREAK:
 			stmt := d.breakTarget
 			if x.Label != nil {
 				stmt = d.labels[x.Label.Name]
 			}
 			if stmt != nil {
 				d.hasBreak[stmt] = true
 			}
 		}

 	case *ast.IfStmt:
 		d.findLabels(x.Body)
 		if x.Else != nil {
 			d.findLabels(x.Else)
 		}

 	case *ast.LabeledStmt:
 		d.labels[x.Label.Name] = x.Stmt
 		d.findLabels(x.Stmt)

 	// These cases are all the same, but the x.Body only works
 	// when the specific type of x is known, so the cases cannot
 	// be merged.
 	case *ast.ForStmt:
 		outer := d.breakTarget
 		d.breakTarget = x
 		d.findLabels(x.Body)
 		d.breakTarget = outer

 	case *ast.RangeStmt:
 		outer := d.breakTarget
 		d.breakTarget = x
 		d.findLabels(x.Body)
 		d.breakTarget = outer

 	case *ast.SelectStmt:
 		outer := d.breakTarget
 		d.breakTarget = x
 		d.findLabels(x.Body)
 		d.breakTarget = outer

 	case *ast.SwitchStmt:
 		outer := d.breakTarget
 		d.breakTarget = x
 		d.findLabels(x.Body)
 		d.breakTarget = outer

 	case *ast.TypeSwitchStmt:
 		outer := d.breakTarget
 		d.breakTarget = x
 		d.findLabels(x.Body)
 		d.breakTarget = outer

 	case *ast.CommClause:
 		for _, stmt := range x.Body {
 			d.findLabels(stmt)
 		}

 	case *ast.CaseClause:
 		for _, stmt := range x.Body {
 			d.findLabels(stmt)
 		}
 	}
 }

 // findDead walks the statement looking for dead code.
 // If d.reachable is false on entry, stmt itself is dead.
 // When findDead returns, d.reachable tells whether the
 // statement following stmt is reachable.
 func (d *deadState) findDead(stmt ast.Stmt) {
 	// Is this a labeled goto target?
 	// If so, assume it is reachable due to the goto.
 	// This is slightly conservative, in that we don't
 	// check that the goto is reachable, so
 	//	L: goto L
 	// will not provoke a warning.
 	// But it's good enough.
 	if x, isLabel := stmt.(*ast.LabeledStmt); isLabel && d.hasGoto[x.Label.Name] {
 		d.reachable = true
 	}

 	if !d.reachable {
 		switch stmt.(type) {
 		case *ast.EmptyStmt:
 			// do not warn about unreachable empty statements
 		default:
 			d.f.Bad(stmt.Pos(), "unreachable code")
 			d.reachable = true // silence error about next statement
 		}
 	}

 	switch x := stmt.(type) {
 	default:
 		d.f.Warnf(x.Pos(), "internal error in findDead: unexpected statement %T", x)

 	case *ast.AssignStmt,
 		*ast.BadStmt,
 		*ast.DeclStmt,
 		*ast.DeferStmt,
 		*ast.EmptyStmt,
 		*ast.GoStmt,
 		*ast.IncDecStmt,
 		*ast.SendStmt:
 		// no control flow

 	case *ast.BlockStmt:
 		for _, stmt := range x.List {
 			d.findDead(stmt)
 		}

 	case *ast.BranchStmt:
 		switch x.Tok {
 		case token.BREAK, token.GOTO, token.FALLTHROUGH:
 			d.reachable = false
 		case token.CONTINUE:
 			// NOTE: We accept "continue" statements as terminating.
 			// They are not necessary in the spec definition of terminating,
 			// because a continue statement cannot be the final statement
 			// before a return. But for the more general problem of syntactically
 			// identifying dead code, continue redirects control flow just
 			// like the other terminating statements.
 			d.reachable = false
 		}

 	case *ast.ExprStmt:
 		// Call to panic?
 		call, ok := x.X.(*ast.CallExpr)
 		if ok {
 			name, ok := call.Fun.(*ast.Ident)
 			if ok && name.Name == "panic" && name.Obj == nil {
 				d.reachable = false
 			}
 		}

 	case *ast.ForStmt:
 		d.findDead(x.Body)
 		d.reachable = x.Cond != nil || d.hasBreak[x]

 	case *ast.IfStmt:
 		d.findDead(x.Body)
 		if x.Else != nil {
 			r := d.reachable
 			d.reachable = true
 			d.findDead(x.Else)
 			d.reachable = d.reachable || r
 		} else {
 			// might not have executed if statement
 			d.reachable = true
 		}

 	case *ast.LabeledStmt:
 		d.findDead(x.Stmt)

 	case *ast.RangeStmt:
 		d.findDead(x.Body)
 		d.reachable = true

 	case *ast.ReturnStmt:
 		d.reachable = false

 	case *ast.SelectStmt:
 		// NOTE: Unlike switch and type switch below, we don't care
 		// whether a select has a default, because a select without a
 		// default blocks until one of the cases can run. That's different
 		// from a switch without a default, which behaves like it has
 		// a default with an empty body.
 		anyReachable := false
 		for _, comm := range x.Body.List {
 			d.reachable = true
 			for _, stmt := range comm.(*ast.CommClause).Body {
 				d.findDead(stmt)
 			}
 			anyReachable = anyReachable || d.reachable
 		}
 		d.reachable = anyReachable || d.hasBreak[x]

 	case *ast.SwitchStmt:
 		anyReachable := false
 		hasDefault := false
 		for _, cas := range x.Body.List {
 			cc := cas.(*ast.CaseClause)
 			if cc.List == nil {
 				hasDefault = true
 			}
 			d.reachable = true
 			for _, stmt := range cc.Body {
 				d.findDead(stmt)
 			}
 			anyReachable = anyReachable || d.reachable
 		}
 		d.reachable = anyReachable || d.hasBreak[x] || !hasDefault

 	case *ast.TypeSwitchStmt:
 		anyReachable := false
 		hasDefault := false
 		for _, cas := range x.Body.List {
 			cc := cas.(*ast.CaseClause)
 			if cc.List == nil {
 				hasDefault = true
 			}
 			d.reachable = true
 			for _, stmt := range cc.Body {
 				d.findDead(stmt)
 			}
 			anyReachable = anyReachable || d.reachable
 		}
 		d.reachable = anyReachable || d.hasBreak[x] || !hasDefault
 	}
 }
	// 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.

	// Check for syntactically unreachable code.

	package main

	import (
	"go/ast"
	"go/token"
	)

	func init() {
	register("unreachable",
	"check for unreachable code",
	checkUnreachable,
	funcDecl, funcLit)
	}

	type deadState struct {
	f *File
	hasBreak map[ast.Stmt]bool
	hasGoto map[string]bool
	labels map[string]ast.Stmt
	breakTarget ast.Stmt

	reachable bool
	}

	// checkUnreachable checks a function body for dead code.
	//
	// TODO(adonovan): use the new cfg package, which is more precise.
	func checkUnreachable(f *File, node ast.Node) {
	var body *ast.BlockStmt
	switch n := node.(type) {
	case *ast.FuncDecl:
	body = n.Body
	case *ast.FuncLit:
	body = n.Body
	}
	if body == nil {
	return
	}

	d := &deadState{
	f: f,
	hasBreak: make(map[ast.Stmt]bool),
	hasGoto: make(map[string]bool),
	labels: make(map[string]ast.Stmt),
	}

	d.findLabels(body)

	d.reachable = true
	d.findDead(body)
	}

	// findLabels gathers information about the labels defined and used by stmt
	// and about which statements break, whether a label is involved or not.
	func (d *deadState) findLabels(stmt ast.Stmt) {
	switch x := stmt.(type) {
	default:
	d.f.Warnf(x.Pos(), "internal error in findLabels: unexpected statement %T", x)

	case *ast.AssignStmt,
	*ast.BadStmt,
	*ast.DeclStmt,
	*ast.DeferStmt,
	*ast.EmptyStmt,
	*ast.ExprStmt,
	*ast.GoStmt,
	*ast.IncDecStmt,
	*ast.ReturnStmt,
	*ast.SendStmt:
	// no statements inside

	case *ast.BlockStmt:
	for _, stmt := range x.List {
	d.findLabels(stmt)
	}

	case *ast.BranchStmt:
	switch x.Tok {
	case token.GOTO:
	if x.Label != nil {
	d.hasGoto[x.Label.Name] = true
	}

	case token.BREAK:
	stmt := d.breakTarget
	if x.Label != nil {
	stmt = d.labels[x.Label.Name]
	}
	if stmt != nil {
	d.hasBreak[stmt] = true
	}
	}

	case *ast.IfStmt:
	d.findLabels(x.Body)
	if x.Else != nil {
	d.findLabels(x.Else)
	}

	case *ast.LabeledStmt:
	d.labels[x.Label.Name] = x.Stmt
	d.findLabels(x.Stmt)

	// These cases are all the same, but the x.Body only works
	// when the specific type of x is known, so the cases cannot
	// be merged.
	case *ast.ForStmt:
	outer := d.breakTarget
	d.breakTarget = x
	d.findLabels(x.Body)
	d.breakTarget = outer

	case *ast.RangeStmt:
	outer := d.breakTarget
	d.breakTarget = x
	d.findLabels(x.Body)
	d.breakTarget = outer

	case *ast.SelectStmt:
	outer := d.breakTarget
	d.breakTarget = x
	d.findLabels(x.Body)
	d.breakTarget = outer

	case *ast.SwitchStmt:
	outer := d.breakTarget
	d.breakTarget = x
	d.findLabels(x.Body)
	d.breakTarget = outer

	case *ast.TypeSwitchStmt:
	outer := d.breakTarget
	d.breakTarget = x
	d.findLabels(x.Body)
	d.breakTarget = outer

	case *ast.CommClause:
	for _, stmt := range x.Body {
	d.findLabels(stmt)
	}

	case *ast.CaseClause:
	for _, stmt := range x.Body {
	d.findLabels(stmt)
	}
	}
	}

	// findDead walks the statement looking for dead code.
	// If d.reachable is false on entry, stmt itself is dead.
	// When findDead returns, d.reachable tells whether the
	// statement following stmt is reachable.
	func (d *deadState) findDead(stmt ast.Stmt) {
	// Is this a labeled goto target?
	// If so, assume it is reachable due to the goto.
	// This is slightly conservative, in that we don't
	// check that the goto is reachable, so
	// L: goto L
	// will not provoke a warning.
	// But it's good enough.
	if x, isLabel := stmt.(*ast.LabeledStmt); isLabel && d.hasGoto[x.Label.Name] {
	d.reachable = true
	}

	if !d.reachable {
	switch stmt.(type) {
	case *ast.EmptyStmt:
	// do not warn about unreachable empty statements
	default:
	d.f.Bad(stmt.Pos(), "unreachable code")
	d.reachable = true // silence error about next statement
	}
	}

	switch x := stmt.(type) {
	default:
	d.f.Warnf(x.Pos(), "internal error in findDead: unexpected statement %T", x)

	case *ast.AssignStmt,
	*ast.BadStmt,
	*ast.DeclStmt,
	*ast.DeferStmt,
	*ast.EmptyStmt,
	*ast.GoStmt,
	*ast.IncDecStmt,
	*ast.SendStmt:
	// no control flow

	case *ast.BlockStmt:
	for _, stmt := range x.List {
	d.findDead(stmt)
	}

	case *ast.BranchStmt:
	switch x.Tok {
	case token.BREAK, token.GOTO, token.FALLTHROUGH:
	d.reachable = false
	case token.CONTINUE:
	// NOTE: We accept "continue" statements as terminating.
	// They are not necessary in the spec definition of terminating,
	// because a continue statement cannot be the final statement
	// before a return. But for the more general problem of syntactically
	// identifying dead code, continue redirects control flow just
	// like the other terminating statements.
	d.reachable = false
	}

	case *ast.ExprStmt:
	// Call to panic?
	call, ok := x.X.(*ast.CallExpr)
	if ok {
	name, ok := call.Fun.(*ast.Ident)
	if ok && name.Name == "panic" && name.Obj == nil {
	d.reachable = false
	}
	}

	case *ast.ForStmt:
	d.findDead(x.Body)
	d.reachable = x.Cond != nil \|\| d.hasBreak[x]

	case *ast.IfStmt:
	d.findDead(x.Body)
	if x.Else != nil {
	r := d.reachable
	d.reachable = true
	d.findDead(x.Else)
	d.reachable = d.reachable \|\| r
	} else {
	// might not have executed if statement
	d.reachable = true
	}

	case *ast.LabeledStmt:
	d.findDead(x.Stmt)

	case *ast.RangeStmt:
	d.findDead(x.Body)
	d.reachable = true

	case *ast.ReturnStmt:
	d.reachable = false

	case *ast.SelectStmt:
	// NOTE: Unlike switch and type switch below, we don't care
	// whether a select has a default, because a select without a
	// default blocks until one of the cases can run. That's different
	// from a switch without a default, which behaves like it has
	// a default with an empty body.
	anyReachable := false
	for _, comm := range x.Body.List {
	d.reachable = true
	for _, stmt := range comm.(*ast.CommClause).Body {
	d.findDead(stmt)
	}
	anyReachable = anyReachable \|\| d.reachable
	}
	d.reachable = anyReachable \|\| d.hasBreak[x]

	case *ast.SwitchStmt:
	anyReachable := false
	hasDefault := false
	for _, cas := range x.Body.List {
	cc := cas.(*ast.CaseClause)
	if cc.List == nil {
	hasDefault = true
	}
	d.reachable = true
	for _, stmt := range cc.Body {
	d.findDead(stmt)
	}
	anyReachable = anyReachable \|\| d.reachable
	}
	d.reachable = anyReachable \|\| d.hasBreak[x] \|\| !hasDefault

	case *ast.TypeSwitchStmt:
	anyReachable := false
	hasDefault := false
	for _, cas := range x.Body.List {
	cc := cas.(*ast.CaseClause)
	if cc.List == nil {
	hasDefault = true
	}
	d.reachable = true
	for _, stmt := range cc.Body {
	d.findDead(stmt)
	}
	anyReachable = anyReachable \|\| d.reachable
	}
	d.reachable = anyReachable \|\| d.hasBreak[x] \|\| !hasDefault
	}
	}