src/pkg/exp/ogle/vars.go - go - Git at Google

 // Copyright 2009 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 ogle

 import (
 	"debug/gosym"
 	"debug/proc"
 	"exp/eval"
 	"log"
 	"os"
 )

 /*
  * Remote frame pointers
  */

 // A NotOnStack error occurs when attempting to access a variable in a
 // remote frame where that remote frame is not on the current stack.
 type NotOnStack struct {
 	Fn        *gosym.Func
 	Goroutine *Goroutine
 }

 func (e NotOnStack) String() string {
 	return "function " + e.Fn.Name + " not on " + e.Goroutine.String() + "'s stack"
 }

 // A remoteFramePtr is an implementation of eval.PtrValue that
 // represents a pointer to a function frame in a remote process.  When
 // accessed, this locates the function on the current goroutine's
 // stack and returns a structure containing the local variables of
 // that function.
 type remoteFramePtr struct {
 	p  *Process
 	fn *gosym.Func
 	rt *remoteType
 }

 func (v remoteFramePtr) String() string {
 	// TODO(austin): This could be a really awesome string method
 	return "<remote frame>"
 }

 func (v remoteFramePtr) Assign(t *eval.Thread, o eval.Value) {
 	v.Set(t, o.(eval.PtrValue).Get(t))
 }

 func (v remoteFramePtr) Get(t *eval.Thread) eval.Value {
 	g := v.p.curGoroutine
 	if g == nil || g.frame == nil {
 		t.Abort(NoCurrentGoroutine{})
 	}

 	for f := g.frame; f != nil; f = f.aOuter(t) {
 		if f.fn != v.fn {
 			continue
 		}

 		// TODO(austin): Register for shootdown with f
 		return v.rt.mk(remote{f.fp, v.p})
 	}

 	t.Abort(NotOnStack{v.fn, g})
 	panic("fail")
 }

 func (v remoteFramePtr) Set(t *eval.Thread, x eval.Value) {
 	// Theoretically this could be a static error.  If remote
 	// packages were packages, remote frames could just be defined
 	// as constants.
 	t.Abort(ReadOnlyError("remote frames cannot be assigned to"))
 }

 /*
  * Remote packages
  */

 // TODO(austin): Remote packages are implemented as structs right now,
 // which has some weird consequences.  You can attempt to assign to a
 // remote package.  It also produces terrible error messages.
 // Ideally, these would actually be packages, but somehow first-class
 // so they could be assigned to other names.

 // A remotePackage is an implementation of eval.StructValue that
 // represents a package in a remote process.  It's essentially a
 // regular struct, except it cannot be assigned to.
 type remotePackage struct {
 	defs []eval.Value
 }

 func (v remotePackage) String() string { return "<remote package>" }

 func (v remotePackage) Assign(t *eval.Thread, o eval.Value) {
 	t.Abort(ReadOnlyError("remote packages cannot be assigned to"))
 }

 func (v remotePackage) Get(t *eval.Thread) eval.StructValue {
 	return v
 }

 func (v remotePackage) Field(t *eval.Thread, i int) eval.Value {
 	return v.defs[i]
 }

 /*
  * Remote variables
  */

 // populateWorld defines constants in the given world for each package
 // in this process.  These packages are structs that, in turn, contain
 // fields for each global and function in that package.
 func (p *Process) populateWorld(w *eval.World) os.Error {
 	type def struct {
 		t eval.Type
 		v eval.Value
 	}
 	packages := make(map[string]map[string]def)

 	for _, s := range p.syms.Syms {
 		if s.ReceiverName() != "" {
 			// TODO(austin)
 			continue
 		}

 		// Package
 		pkgName := s.PackageName()
 		switch pkgName {
 		case "", "type", "extratype", "string", "go":
 			// "go" is really "go.string"
 			continue
 		}
 		pkg, ok := packages[pkgName]
 		if !ok {
 			pkg = make(map[string]def)
 			packages[pkgName] = pkg
 		}

 		// Symbol name
 		name := s.BaseName()
 		if _, ok := pkg[name]; ok {
 			log.Printf("Multiple definitions of symbol %s", s.Name)
 			continue
 		}

 		// Symbol type
 		rt, err := p.typeOfSym(&s)
 		if err != nil {
 			return err
 		}

 		// Definition
 		switch s.Type {
 		case 'D', 'd', 'B', 'b':
 			// Global variable
 			if rt == nil {
 				continue
 			}
 			pkg[name] = def{rt.Type, rt.mk(remote{proc.Word(s.Value), p})}

 		case 'T', 't', 'L', 'l':
 			// Function
 			s := s.Func
 			// TODO(austin): Ideally, this would *also* be
 			// callable.  How does that interact with type
 			// conversion syntax?
 			rt, err := p.makeFrameType(s)
 			if err != nil {
 				return err
 			}
 			pkg[name] = def{eval.NewPtrType(rt.Type), remoteFramePtr{p, s, rt}}
 		}
 	}

 	// TODO(austin): Define remote types

 	// Define packages
 	for pkgName, defs := range packages {
 		fields := make([]eval.StructField, len(defs))
 		vals := make([]eval.Value, len(defs))
 		i := 0
 		for name, def := range defs {
 			fields[i].Name = name
 			fields[i].Type = def.t
 			vals[i] = def.v
 			i++
 		}
 		pkgType := eval.NewStructType(fields)
 		pkgVal := remotePackage{vals}

 		err := w.DefineConst(pkgName, pkgType, pkgVal)
 		if err != nil {
 			log.Printf("while defining package %s: %v", pkgName, err)
 		}
 	}

 	return nil
 }

 // typeOfSym returns the type associated with a symbol.  If the symbol
 // has no type, returns nil.
 func (p *Process) typeOfSym(s *gosym.Sym) (*remoteType, os.Error) {
 	if s.GoType == 0 {
 		return nil, nil
 	}
 	addr := proc.Word(s.GoType)
 	var rt *remoteType
 	err := try(func(a aborter) { rt = parseRemoteType(a, p.runtime.Type.mk(remote{addr, p}).(remoteStruct)) })
 	if err != nil {
 		return nil, err
 	}
 	return rt, nil
 }

 // makeFrameType constructs a struct type for the frame of a function.
 // The offsets in this struct type are such that the struct can be
 // instantiated at this function's frame pointer.
 func (p *Process) makeFrameType(s *gosym.Func) (*remoteType, os.Error) {
 	n := len(s.Params) + len(s.Locals)
 	fields := make([]eval.StructField, n)
 	layout := make([]remoteStructField, n)
 	i := 0

 	// TODO(austin): There can be multiple locals/parameters with
 	// the same name.  We probably need liveness information to do
 	// anything about this.  Once we have that, perhaps we give
 	// such fields interface{} type?  Or perhaps we disambiguate
 	// the names with numbers.  Disambiguation is annoying for
 	// things like "i", where there's an obvious right answer.

 	for _, param := range s.Params {
 		rt, err := p.typeOfSym(param)
 		if err != nil {
 			return nil, err
 		}
 		if rt == nil {
 			//fmt.Printf(" (no type)\n");
 			continue
 		}
 		// TODO(austin): Why do local variables carry their
 		// package name?
 		fields[i].Name = param.BaseName()
 		fields[i].Type = rt.Type
 		// Parameters have positive offsets from FP
 		layout[i].offset = int(param.Value)
 		layout[i].fieldType = rt
 		i++
 	}

 	for _, local := range s.Locals {
 		rt, err := p.typeOfSym(local)
 		if err != nil {
 			return nil, err
 		}
 		if rt == nil {
 			continue
 		}
 		fields[i].Name = local.BaseName()
 		fields[i].Type = rt.Type
 		// Locals have negative offsets from FP - PtrSize
 		layout[i].offset = -int(local.Value) - p.PtrSize()
 		layout[i].fieldType = rt
 		i++
 	}

 	fields = fields[0:i]
 	layout = layout[0:i]
 	t := eval.NewStructType(fields)
 	mk := func(r remote) eval.Value { return remoteStruct{r, layout} }
 	return &remoteType{t, 0, 0, mk}, nil
 }
	// Copyright 2009 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 ogle

	import (
	"debug/gosym"
	"debug/proc"
	"exp/eval"
	"log"
	"os"
	)

	/*
	* Remote frame pointers
	*/

	// A NotOnStack error occurs when attempting to access a variable in a
	// remote frame where that remote frame is not on the current stack.
	type NotOnStack struct {
	Fn *gosym.Func
	Goroutine *Goroutine
	}

	func (e NotOnStack) String() string {
	return "function " + e.Fn.Name + " not on " + e.Goroutine.String() + "'s stack"
	}

	// A remoteFramePtr is an implementation of eval.PtrValue that
	// represents a pointer to a function frame in a remote process. When
	// accessed, this locates the function on the current goroutine's
	// stack and returns a structure containing the local variables of
	// that function.
	type remoteFramePtr struct {
	p *Process
	fn *gosym.Func
	rt *remoteType
	}

	func (v remoteFramePtr) String() string {
	// TODO(austin): This could be a really awesome string method
	return "<remote frame>"
	}

	func (v remoteFramePtr) Assign(t *eval.Thread, o eval.Value) {
	v.Set(t, o.(eval.PtrValue).Get(t))
	}

	func (v remoteFramePtr) Get(t *eval.Thread) eval.Value {
	g := v.p.curGoroutine
	if g == nil \|\| g.frame == nil {
	t.Abort(NoCurrentGoroutine{})
	}

	for f := g.frame; f != nil; f = f.aOuter(t) {
	if f.fn != v.fn {
	continue
	}

	// TODO(austin): Register for shootdown with f
	return v.rt.mk(remote{f.fp, v.p})
	}

	t.Abort(NotOnStack{v.fn, g})
	panic("fail")
	}

	func (v remoteFramePtr) Set(t *eval.Thread, x eval.Value) {
	// Theoretically this could be a static error. If remote
	// packages were packages, remote frames could just be defined
	// as constants.
	t.Abort(ReadOnlyError("remote frames cannot be assigned to"))
	}

	/*
	* Remote packages
	*/

	// TODO(austin): Remote packages are implemented as structs right now,
	// which has some weird consequences. You can attempt to assign to a
	// remote package. It also produces terrible error messages.
	// Ideally, these would actually be packages, but somehow first-class
	// so they could be assigned to other names.

	// A remotePackage is an implementation of eval.StructValue that
	// represents a package in a remote process. It's essentially a
	// regular struct, except it cannot be assigned to.
	type remotePackage struct {
	defs []eval.Value
	}

	func (v remotePackage) String() string { return "<remote package>" }

	func (v remotePackage) Assign(t *eval.Thread, o eval.Value) {
	t.Abort(ReadOnlyError("remote packages cannot be assigned to"))
	}

	func (v remotePackage) Get(t *eval.Thread) eval.StructValue {
	return v
	}

	func (v remotePackage) Field(t *eval.Thread, i int) eval.Value {
	return v.defs[i]
	}

	/*
	* Remote variables
	*/

	// populateWorld defines constants in the given world for each package
	// in this process. These packages are structs that, in turn, contain
	// fields for each global and function in that package.
	func (p Process) populateWorld(w eval.World) os.Error {
	type def struct {
	t eval.Type
	v eval.Value
	}
	packages := make(map[string]map[string]def)

	for _, s := range p.syms.Syms {
	if s.ReceiverName() != "" {
	// TODO(austin)
	continue
	}

	// Package
	pkgName := s.PackageName()
	switch pkgName {
	case "", "type", "extratype", "string", "go":
	// "go" is really "go.string"
	continue
	}
	pkg, ok := packages[pkgName]
	if !ok {
	pkg = make(map[string]def)
	packages[pkgName] = pkg
	}

	// Symbol name
	name := s.BaseName()
	if _, ok := pkg[name]; ok {
	log.Printf("Multiple definitions of symbol %s", s.Name)
	continue
	}

	// Symbol type
	rt, err := p.typeOfSym(&s)
	if err != nil {
	return err
	}

	// Definition
	switch s.Type {
	case 'D', 'd', 'B', 'b':
	// Global variable
	if rt == nil {
	continue
	}
	pkg[name] = def{rt.Type, rt.mk(remote{proc.Word(s.Value), p})}

	case 'T', 't', 'L', 'l':
	// Function
	s := s.Func
	// TODO(austin): Ideally, this would also be
	// callable. How does that interact with type
	// conversion syntax?
	rt, err := p.makeFrameType(s)
	if err != nil {
	return err
	}
	pkg[name] = def{eval.NewPtrType(rt.Type), remoteFramePtr{p, s, rt}}
	}
	}

	// TODO(austin): Define remote types

	// Define packages
	for pkgName, defs := range packages {
	fields := make([]eval.StructField, len(defs))
	vals := make([]eval.Value, len(defs))
	i := 0
	for name, def := range defs {
	fields[i].Name = name
	fields[i].Type = def.t
	vals[i] = def.v
	i++
	}
	pkgType := eval.NewStructType(fields)
	pkgVal := remotePackage{vals}

	err := w.DefineConst(pkgName, pkgType, pkgVal)
	if err != nil {
	log.Printf("while defining package %s: %v", pkgName, err)
	}
	}

	return nil
	}

	// typeOfSym returns the type associated with a symbol. If the symbol
	// has no type, returns nil.
	func (p Process) typeOfSym(s gosym.Sym) (*remoteType, os.Error) {
	if s.GoType == 0 {
	return nil, nil
	}
	addr := proc.Word(s.GoType)
	var rt *remoteType
	err := try(func(a aborter) { rt = parseRemoteType(a, p.runtime.Type.mk(remote{addr, p}).(remoteStruct)) })
	if err != nil {
	return nil, err
	}
	return rt, nil
	}

	// makeFrameType constructs a struct type for the frame of a function.
	// The offsets in this struct type are such that the struct can be
	// instantiated at this function's frame pointer.
	func (p Process) makeFrameType(s gosym.Func) (*remoteType, os.Error) {
	n := len(s.Params) + len(s.Locals)
	fields := make([]eval.StructField, n)
	layout := make([]remoteStructField, n)
	i := 0

	// TODO(austin): There can be multiple locals/parameters with
	// the same name. We probably need liveness information to do
	// anything about this. Once we have that, perhaps we give
	// such fields interface{} type? Or perhaps we disambiguate
	// the names with numbers. Disambiguation is annoying for
	// things like "i", where there's an obvious right answer.

	for _, param := range s.Params {
	rt, err := p.typeOfSym(param)
	if err != nil {
	return nil, err
	}
	if rt == nil {
	//fmt.Printf(" (no type)\n");
	continue
	}
	// TODO(austin): Why do local variables carry their
	// package name?
	fields[i].Name = param.BaseName()
	fields[i].Type = rt.Type
	// Parameters have positive offsets from FP
	layout[i].offset = int(param.Value)
	layout[i].fieldType = rt
	i++
	}

	for _, local := range s.Locals {
	rt, err := p.typeOfSym(local)
	if err != nil {
	return nil, err
	}
	if rt == nil {
	continue
	}
	fields[i].Name = local.BaseName()
	fields[i].Type = rt.Type
	// Locals have negative offsets from FP - PtrSize
	layout[i].offset = -int(local.Value) - p.PtrSize()
	layout[i].fieldType = rt
	i++
	}

	fields = fields[0:i]
	layout = layout[0:i]
	t := eval.NewStructType(fields)
	mk := func(r remote) eval.Value { return remoteStruct{r, layout} }
	return &remoteType{t, 0, 0, mk}, nil
	}