go/ssa/source.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 ssa

 // This file defines utilities for working with source positions
 // or source-level named entities ("objects").

 // TODO(adonovan): test that {Value,Instruction}.Pos() positions match
 // the originating syntax, as specified.

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

 // EnclosingFunction returns the function that contains the syntax
 // node denoted by path.
 //
 // Syntax associated with package-level variable specifications is
 // enclosed by the package's init() function.
 //
 // Returns nil if not found; reasons might include:
 //    - the node is not enclosed by any function.
 //    - the node is within an anonymous function (FuncLit) and
 //      its SSA function has not been created yet
 //      (pkg.Build() has not yet been called).
 //
 func EnclosingFunction(pkg *Package, path []ast.Node) *Function {
 	// Start with package-level function...
 	fn := findEnclosingPackageLevelFunction(pkg, path)
 	if fn == nil {
 		return nil // not in any function
 	}

 	// ...then walk down the nested anonymous functions.
 	n := len(path)
 outer:
 	for i := range path {
 		if lit, ok := path[n-1-i].(*ast.FuncLit); ok {
 			for _, anon := range fn.AnonFuncs {
 				if anon.Pos() == lit.Type.Func {
 					fn = anon
 					continue outer
 				}
 			}
 			// SSA function not found:
 			// - package not yet built, or maybe
 			// - builder skipped FuncLit in dead block
 			//   (in principle; but currently the Builder
 			//   generates even dead FuncLits).
 			return nil
 		}
 	}
 	return fn
 }

 // HasEnclosingFunction returns true if the AST node denoted by path
 // is contained within the declaration of some function or
 // package-level variable.
 //
 // Unlike EnclosingFunction, the behaviour of this function does not
 // depend on whether SSA code for pkg has been built, so it can be
 // used to quickly reject check inputs that will cause
 // EnclosingFunction to fail, prior to SSA building.
 //
 func HasEnclosingFunction(pkg *Package, path []ast.Node) bool {
 	return findEnclosingPackageLevelFunction(pkg, path) != nil
 }

 // findEnclosingPackageLevelFunction returns the Function
 // corresponding to the package-level function enclosing path.
 //
 func findEnclosingPackageLevelFunction(pkg *Package, path []ast.Node) *Function {
 	if n := len(path); n >= 2 { // [... {Gen,Func}Decl File]
 		switch decl := path[n-2].(type) {
 		case *ast.GenDecl:
 			if decl.Tok == token.VAR && n >= 3 {
 				// Package-level 'var' initializer.
 				return pkg.init
 			}

 		case *ast.FuncDecl:
 			if decl.Recv == nil && decl.Name.Name == "init" {
 				// Explicit init() function.
 				for _, b := range pkg.init.Blocks {
 					for _, instr := range b.Instrs {
 						if instr, ok := instr.(*Call); ok {
 							if callee, ok := instr.Call.Value.(*Function); ok && callee.Pkg == pkg && callee.Pos() == decl.Name.NamePos {
 								return callee
 							}
 						}
 					}
 				}
 				// Hack: return non-nil when SSA is not yet
 				// built so that HasEnclosingFunction works.
 				return pkg.init
 			}
 			// Declared function/method.
 			return findNamedFunc(pkg, decl.Name.NamePos)
 		}
 	}
 	return nil // not in any function
 }

 // findNamedFunc returns the named function whose FuncDecl.Ident is at
 // position pos.
 //
 func findNamedFunc(pkg *Package, pos token.Pos) *Function {
 	// Look at all package members and method sets of named types.
 	// Not very efficient.
 	for _, mem := range pkg.Members {
 		switch mem := mem.(type) {
 		case *Function:
 			if mem.Pos() == pos {
 				return mem
 			}
 		case *Type:
 			mset := pkg.Prog.MethodSets.MethodSet(types.NewPointer(mem.Type()))
 			for i, n := 0, mset.Len(); i < n; i++ {
 				// Don't call Program.Method: avoid creating wrappers.
 				obj := mset.At(i).Obj().(*types.Func)
 				if obj.Pos() == pos {
 					return pkg.values[obj].(*Function)
 				}
 			}
 		}
 	}
 	return nil
 }

 // ValueForExpr returns the SSA Value that corresponds to non-constant
 // expression e.
 //
 // It returns nil if no value was found, e.g.
 //    - the expression is not lexically contained within f;
 //    - f was not built with debug information; or
 //    - e is a constant expression.  (For efficiency, no debug
 //      information is stored for constants. Use
 //      go/types.Info.Types[e].Value instead.)
 //    - e is a reference to nil or a built-in function.
 //    - the value was optimised away.
 //
 // If e is an addressable expression used in an lvalue context,
 // value is the address denoted by e, and isAddr is true.
 //
 // The types of e (or &e, if isAddr) and the result are equal
 // (modulo "untyped" bools resulting from comparisons).
 //
 // (Tip: to find the ssa.Value given a source position, use
 // astutil.PathEnclosingInterval to locate the ast.Node, then
 // EnclosingFunction to locate the Function, then ValueForExpr to find
 // the ssa.Value.)
 //
 func (f *Function) ValueForExpr(e ast.Expr) (value Value, isAddr bool) {
 	if f.debugInfo() { // (opt)
 		e = unparen(e)
 		for _, b := range f.Blocks {
 			for _, instr := range b.Instrs {
 				if ref, ok := instr.(*DebugRef); ok {
 					if ref.Expr == e {
 						return ref.X, ref.IsAddr
 					}
 				}
 			}
 		}
 	}
 	return
 }

 // --- Lookup functions for source-level named entities (types.Objects) ---

 // Package returns the SSA Package corresponding to the specified
 // type-checker package object.
 // It returns nil if no such SSA package has been created.
 //
 func (prog *Program) Package(obj *types.Package) *Package {
 	return prog.packages[obj]
 }

 // packageLevelValue returns the package-level value corresponding to
 // the specified named object, which may be a package-level const
 // (*Const), var (*Global) or func (*Function) of some package in
 // prog.  It returns nil if the object is not found.
 //
 func (prog *Program) packageLevelValue(obj types.Object) Value {
 	if pkg, ok := prog.packages[obj.Pkg()]; ok {
 		return pkg.values[obj]
 	}
 	return nil
 }

 // FuncValue returns the concrete Function denoted by the source-level
 // named function obj, or nil if obj denotes an interface method.
 //
 // TODO(adonovan): check the invariant that obj.Type() matches the
 // result's Signature, both in the params/results and in the receiver.
 //
 func (prog *Program) FuncValue(obj *types.Func) *Function {
 	fn, _ := prog.packageLevelValue(obj).(*Function)
 	return fn
 }

 // ConstValue returns the SSA Value denoted by the source-level named
 // constant obj.
 //
 func (prog *Program) ConstValue(obj *types.Const) *Const {
 	// TODO(adonovan): opt: share (don't reallocate)
 	// Consts for const objects and constant ast.Exprs.

 	// Universal constant? {true,false,nil}
 	if obj.Parent() == types.Universe {
 		return NewConst(obj.Val(), obj.Type())
 	}
 	// Package-level named constant?
 	if v := prog.packageLevelValue(obj); v != nil {
 		return v.(*Const)
 	}
 	return NewConst(obj.Val(), obj.Type())
 }

 // VarValue returns the SSA Value that corresponds to a specific
 // identifier denoting the source-level named variable obj.
 //
 // VarValue returns nil if a local variable was not found, perhaps
 // because its package was not built, the debug information was not
 // requested during SSA construction, or the value was optimized away.
 //
 // ref is the path to an ast.Ident (e.g. from PathEnclosingInterval),
 // and that ident must resolve to obj.
 //
 // pkg is the package enclosing the reference.  (A reference to a var
 // always occurs within a function, so we need to know where to find it.)
 //
 // If the identifier is a field selector and its base expression is
 // non-addressable, then VarValue returns the value of that field.
 // For example:
 //    func f() struct {x int}
 //    f().x  // VarValue(x) returns a *Field instruction of type int
 //
 // All other identifiers denote addressable locations (variables).
 // For them, VarValue may return either the variable's address or its
 // value, even when the expression is evaluated only for its value; the
 // situation is reported by isAddr, the second component of the result.
 //
 // If !isAddr, the returned value is the one associated with the
 // specific identifier.  For example,
 //       var x int    // VarValue(x) returns Const 0 here
 //       x = 1        // VarValue(x) returns Const 1 here
 //
 // It is not specified whether the value or the address is returned in
 // any particular case, as it may depend upon optimizations performed
 // during SSA code generation, such as registerization, constant
 // folding, avoidance of materialization of subexpressions, etc.
 //
 func (prog *Program) VarValue(obj *types.Var, pkg *Package, ref []ast.Node) (value Value, isAddr bool) {
 	// All references to a var are local to some function, possibly init.
 	fn := EnclosingFunction(pkg, ref)
 	if fn == nil {
 		return // e.g. def of struct field; SSA not built?
 	}

 	id := ref[0].(*ast.Ident)

 	// Defining ident of a parameter?
 	if id.Pos() == obj.Pos() {
 		for _, param := range fn.Params {
 			if param.Object() == obj {
 				return param, false
 			}
 		}
 	}

 	// Other ident?
 	for _, b := range fn.Blocks {
 		for _, instr := range b.Instrs {
 			if dr, ok := instr.(*DebugRef); ok {
 				if dr.Pos() == id.Pos() {
 					return dr.X, dr.IsAddr
 				}
 			}
 		}
 	}

 	// Defining ident of package-level var?
 	if v := prog.packageLevelValue(obj); v != nil {
 		return v.(*Global), true
 	}

 	return // e.g. debug info not requested, or var optimized away
 }
	// 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 ssa

	// This file defines utilities for working with source positions
	// or source-level named entities ("objects").

	// TODO(adonovan): test that {Value,Instruction}.Pos() positions match
	// the originating syntax, as specified.

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

	// EnclosingFunction returns the function that contains the syntax
	// node denoted by path.
	//
	// Syntax associated with package-level variable specifications is
	// enclosed by the package's init() function.
	//
	// Returns nil if not found; reasons might include:
	// - the node is not enclosed by any function.
	// - the node is within an anonymous function (FuncLit) and
	// its SSA function has not been created yet
	// (pkg.Build() has not yet been called).
	//
	func EnclosingFunction(pkg Package, path []ast.Node) Function {
	// Start with package-level function...
	fn := findEnclosingPackageLevelFunction(pkg, path)
	if fn == nil {
	return nil // not in any function
	}

	// ...then walk down the nested anonymous functions.
	n := len(path)
	outer:
	for i := range path {
	if lit, ok := path[n-1-i].(*ast.FuncLit); ok {
	for _, anon := range fn.AnonFuncs {
	if anon.Pos() == lit.Type.Func {
	fn = anon
	continue outer
	}
	}
	// SSA function not found:
	// - package not yet built, or maybe
	// - builder skipped FuncLit in dead block
	// (in principle; but currently the Builder
	// generates even dead FuncLits).
	return nil
	}
	}
	return fn
	}

	// HasEnclosingFunction returns true if the AST node denoted by path
	// is contained within the declaration of some function or
	// package-level variable.
	//
	// Unlike EnclosingFunction, the behaviour of this function does not
	// depend on whether SSA code for pkg has been built, so it can be
	// used to quickly reject check inputs that will cause
	// EnclosingFunction to fail, prior to SSA building.
	//
	func HasEnclosingFunction(pkg *Package, path []ast.Node) bool {
	return findEnclosingPackageLevelFunction(pkg, path) != nil
	}

	// findEnclosingPackageLevelFunction returns the Function
	// corresponding to the package-level function enclosing path.
	//
	func findEnclosingPackageLevelFunction(pkg Package, path []ast.Node) Function {
	if n := len(path); n >= 2 { // [... {Gen,Func}Decl File]
	switch decl := path[n-2].(type) {
	case *ast.GenDecl:
	if decl.Tok == token.VAR && n >= 3 {
	// Package-level 'var' initializer.
	return pkg.init
	}

	case *ast.FuncDecl:
	if decl.Recv == nil && decl.Name.Name == "init" {
	// Explicit init() function.
	for _, b := range pkg.init.Blocks {
	for _, instr := range b.Instrs {
	if instr, ok := instr.(*Call); ok {
	if callee, ok := instr.Call.Value.(*Function); ok && callee.Pkg == pkg && callee.Pos() == decl.Name.NamePos {
	return callee
	}
	}
	}
	}
	// Hack: return non-nil when SSA is not yet
	// built so that HasEnclosingFunction works.
	return pkg.init
	}
	// Declared function/method.
	return findNamedFunc(pkg, decl.Name.NamePos)
	}
	}
	return nil // not in any function
	}

	// findNamedFunc returns the named function whose FuncDecl.Ident is at
	// position pos.
	//
	func findNamedFunc(pkg Package, pos token.Pos) Function {
	// Look at all package members and method sets of named types.
	// Not very efficient.
	for _, mem := range pkg.Members {
	switch mem := mem.(type) {
	case *Function:
	if mem.Pos() == pos {
	return mem
	}
	case *Type:
	mset := pkg.Prog.MethodSets.MethodSet(types.NewPointer(mem.Type()))
	for i, n := 0, mset.Len(); i < n; i++ {
	// Don't call Program.Method: avoid creating wrappers.
	obj := mset.At(i).Obj().(*types.Func)
	if obj.Pos() == pos {
	return pkg.values[obj].(*Function)
	}
	}
	}
	}
	return nil
	}

	// ValueForExpr returns the SSA Value that corresponds to non-constant
	// expression e.
	//
	// It returns nil if no value was found, e.g.
	// - the expression is not lexically contained within f;
	// - f was not built with debug information; or
	// - e is a constant expression. (For efficiency, no debug
	// information is stored for constants. Use
	// go/types.Info.Types[e].Value instead.)
	// - e is a reference to nil or a built-in function.
	// - the value was optimised away.
	//
	// If e is an addressable expression used in an lvalue context,
	// value is the address denoted by e, and isAddr is true.
	//
	// The types of e (or &e, if isAddr) and the result are equal
	// (modulo "untyped" bools resulting from comparisons).
	//
	// (Tip: to find the ssa.Value given a source position, use
	// astutil.PathEnclosingInterval to locate the ast.Node, then
	// EnclosingFunction to locate the Function, then ValueForExpr to find
	// the ssa.Value.)
	//
	func (f *Function) ValueForExpr(e ast.Expr) (value Value, isAddr bool) {
	if f.debugInfo() { // (opt)
	e = unparen(e)
	for _, b := range f.Blocks {
	for _, instr := range b.Instrs {
	if ref, ok := instr.(*DebugRef); ok {
	if ref.Expr == e {
	return ref.X, ref.IsAddr
	}
	}
	}
	}
	}
	return
	}

	// --- Lookup functions for source-level named entities (types.Objects) ---

	// Package returns the SSA Package corresponding to the specified
	// type-checker package object.
	// It returns nil if no such SSA package has been created.
	//
	func (prog Program) Package(obj types.Package) *Package {
	return prog.packages[obj]
	}

	// packageLevelValue returns the package-level value corresponding to
	// the specified named object, which may be a package-level const
	// (Const), var (Global) or func (*Function) of some package in
	// prog. It returns nil if the object is not found.
	//
	func (prog *Program) packageLevelValue(obj types.Object) Value {
	if pkg, ok := prog.packages[obj.Pkg()]; ok {
	return pkg.values[obj]
	}
	return nil
	}

	// FuncValue returns the concrete Function denoted by the source-level
	// named function obj, or nil if obj denotes an interface method.
	//
	// TODO(adonovan): check the invariant that obj.Type() matches the
	// result's Signature, both in the params/results and in the receiver.
	//
	func (prog Program) FuncValue(obj types.Func) *Function {
	fn, _ := prog.packageLevelValue(obj).(*Function)
	return fn
	}

	// ConstValue returns the SSA Value denoted by the source-level named
	// constant obj.
	//
	func (prog Program) ConstValue(obj types.Const) *Const {
	// TODO(adonovan): opt: share (don't reallocate)
	// Consts for const objects and constant ast.Exprs.

	// Universal constant? {true,false,nil}
	if obj.Parent() == types.Universe {
	return NewConst(obj.Val(), obj.Type())
	}
	// Package-level named constant?
	if v := prog.packageLevelValue(obj); v != nil {
	return v.(*Const)
	}
	return NewConst(obj.Val(), obj.Type())
	}

	// VarValue returns the SSA Value that corresponds to a specific
	// identifier denoting the source-level named variable obj.
	//
	// VarValue returns nil if a local variable was not found, perhaps
	// because its package was not built, the debug information was not
	// requested during SSA construction, or the value was optimized away.
	//
	// ref is the path to an ast.Ident (e.g. from PathEnclosingInterval),
	// and that ident must resolve to obj.
	//
	// pkg is the package enclosing the reference. (A reference to a var
	// always occurs within a function, so we need to know where to find it.)
	//
	// If the identifier is a field selector and its base expression is
	// non-addressable, then VarValue returns the value of that field.
	// For example:
	// func f() struct {x int}
	// f().x // VarValue(x) returns a *Field instruction of type int
	//
	// All other identifiers denote addressable locations (variables).
	// For them, VarValue may return either the variable's address or its
	// value, even when the expression is evaluated only for its value; the
	// situation is reported by isAddr, the second component of the result.
	//
	// If !isAddr, the returned value is the one associated with the
	// specific identifier. For example,
	// var x int // VarValue(x) returns Const 0 here
	// x = 1 // VarValue(x) returns Const 1 here
	//
	// It is not specified whether the value or the address is returned in
	// any particular case, as it may depend upon optimizations performed
	// during SSA code generation, such as registerization, constant
	// folding, avoidance of materialization of subexpressions, etc.
	//
	func (prog Program) VarValue(obj types.Var, pkg *Package, ref []ast.Node) (value Value, isAddr bool) {
	// All references to a var are local to some function, possibly init.
	fn := EnclosingFunction(pkg, ref)
	if fn == nil {
	return // e.g. def of struct field; SSA not built?
	}

	id := ref[0].(*ast.Ident)

	// Defining ident of a parameter?
	if id.Pos() == obj.Pos() {
	for _, param := range fn.Params {
	if param.Object() == obj {
	return param, false
	}
	}
	}

	// Other ident?
	for _, b := range fn.Blocks {
	for _, instr := range b.Instrs {
	if dr, ok := instr.(*DebugRef); ok {
	if dr.Pos() == id.Pos() {
	return dr.X, dr.IsAddr
	}
	}
	}
	}

	// Defining ident of package-level var?
	if v := prog.packageLevelValue(obj); v != nil {
	return v.(*Global), true
	}

	return // e.g. debug info not requested, or var optimized away
	}