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go/ssa/create.go

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package ssa
// This file implements the CREATE phase of SSA construction.
// See builder.go for explanation.
import (
"fmt"
"go/ast"
"go/token"
"os"
"code.google.com/p/go.tools/go/types"
"code.google.com/p/go.tools/importer"
)
// BuilderMode is a bitmask of options for diagnostics and checking.
type BuilderMode uint
const (
LogPackages BuilderMode = 1 << iota // Dump package inventory to stderr
LogFunctions // Dump function SSA code to stderr
LogSource // Show source locations as SSA builder progresses
SanityCheckFunctions // Perform sanity checking of function bodies
NaiveForm // Build naïve SSA form: don't replace local loads/stores with registers
BuildSerially // Build packages serially, not in parallel.
go.tools/ssa: add debug information for all ast.Idents. This CL adds three new functions to determine the SSA Value for a given syntactic var, func or const object: Program.{Const,Func,Var}Value. Since constants and functions are immutable, the first two only need a types.Object; but each distinct reference to a var may return a distinct Value, so the third requires an ast.Ident parameter too. Debug information for local vars is encoded in the instruction stream in the form of DebugRef instructions, which are a no-op but relate their operand to a particular ident in the AST. The beauty of this approach is that it naturally stays consistent during optimisation passes (e.g. lifting) without additional bookkeeping. DebugRef instructions are only generated if the DebugMode builder flag is set; I plan to make the policy more fine- grained (per function). DebugRef instructions are inserted for: - expr(Ident) for rvalue idents - address.store() for idents that update an lvalue - address.address() for idents that take address of lvalue (this new method replaces all uses of lval.(address).addr) - expr() for all constant expressions - local ValueSpecs with implicit zero initialization (no RHS) (this case doesn't call store() or address()) To ensure we don't forget to emit debug info for uses of Idents, we must use the lvalue mechanism consistently. (Previously, many simple cases had effectively inlined these functions.) Similarly setCallFunc no longer inlines expr(Ident). Also: - Program.Value() has been inlined & specialized. - Program.Package() has moved nearer the new lookup functions. - refactoring: funcSyntax has lost paramFields, resultFields; gained funcType, which provides access to both. - add package-level constants to Package.values map. - opt: don't call localValueSpec for constants. (The resulting code is always optimised away.) There are a number of comments asking whether Literals should have positions. Will address in a follow-up. Added tests of all interesting cases. R=gri CC=golang-dev https://golang.org/cl/11259044
2013-07-15 11:56:46 -06:00
DebugInfo // Include DebugRef instructions [TODO(adonovan): finer grain?]
)
// NewProgram returns a new SSA Program initially containing no
// packages.
//
// fset specifies the mapping from token positions to source location
// that will be used by all ASTs of this program.
//
// mode controls diagnostics and checking during SSA construction.
//
func NewProgram(fset *token.FileSet, mode BuilderMode) *Program {
prog := &Program{
Fset: fset,
PackagesByPath: make(map[string]*Package),
packages: make(map[*types.Package]*Package),
builtins: make(map[types.Object]*Builtin),
concreteMethods: make(map[*types.Func]*Function),
indirectionWrappers: make(map[*Function]*Function),
boundMethodWrappers: make(map[*Function]*Function),
ifaceMethodWrappers: make(map[*types.Func]*Function),
mode: mode,
}
// Create Values for built-in functions.
for i, n := 0, types.Universe.NumEntries(); i < n; i++ {
if obj, ok := types.Universe.At(i).(*types.Func); ok {
prog.builtins[obj] = &Builtin{obj}
}
}
return prog
}
// CreatePackages creates an SSA Package for each type-checker package
// held by imp. All such packages must be error-free.
//
// The created packages may be accessed via the Program.Packages field.
//
// A package in the 'created' state has its Members mapping populated,
// but a subsequent call to Package.Build() or Program.BuildAll() is
// required to build SSA code for the bodies of its functions.
//
func (prog *Program) CreatePackages(imp *importer.Importer) {
// TODO(adonovan): make this idempotent, so that a second call
// to CreatePackages creates only the packages that appeared
// in imp since the first.
for path, info := range imp.Packages {
createPackage(prog, path, info)
}
}
// memberFromObject populates package pkg with a member for the
// typechecker object obj.
//
// For objects from Go source code, syntax is the associated syntax
// tree (for funcs and vars only); it will be used during the build
// phase.
//
func memberFromObject(pkg *Package, obj types.Object, syntax ast.Node) {
name := obj.Name()
switch obj := obj.(type) {
case *types.TypeName:
pkg.Members[name] = &Type{object: obj}
case *types.Const:
c := &NamedConst{
object: obj,
Value: NewConst(obj.Val(), obj.Type()),
}
go.tools/ssa: add debug information for all ast.Idents. This CL adds three new functions to determine the SSA Value for a given syntactic var, func or const object: Program.{Const,Func,Var}Value. Since constants and functions are immutable, the first two only need a types.Object; but each distinct reference to a var may return a distinct Value, so the third requires an ast.Ident parameter too. Debug information for local vars is encoded in the instruction stream in the form of DebugRef instructions, which are a no-op but relate their operand to a particular ident in the AST. The beauty of this approach is that it naturally stays consistent during optimisation passes (e.g. lifting) without additional bookkeeping. DebugRef instructions are only generated if the DebugMode builder flag is set; I plan to make the policy more fine- grained (per function). DebugRef instructions are inserted for: - expr(Ident) for rvalue idents - address.store() for idents that update an lvalue - address.address() for idents that take address of lvalue (this new method replaces all uses of lval.(address).addr) - expr() for all constant expressions - local ValueSpecs with implicit zero initialization (no RHS) (this case doesn't call store() or address()) To ensure we don't forget to emit debug info for uses of Idents, we must use the lvalue mechanism consistently. (Previously, many simple cases had effectively inlined these functions.) Similarly setCallFunc no longer inlines expr(Ident). Also: - Program.Value() has been inlined & specialized. - Program.Package() has moved nearer the new lookup functions. - refactoring: funcSyntax has lost paramFields, resultFields; gained funcType, which provides access to both. - add package-level constants to Package.values map. - opt: don't call localValueSpec for constants. (The resulting code is always optimised away.) There are a number of comments asking whether Literals should have positions. Will address in a follow-up. Added tests of all interesting cases. R=gri CC=golang-dev https://golang.org/cl/11259044
2013-07-15 11:56:46 -06:00
pkg.values[obj] = c.Value
pkg.Members[name] = c
case *types.Var:
spec, _ := syntax.(*ast.ValueSpec)
g := &Global{
Pkg: pkg,
name: name,
object: obj,
typ: types.NewPointer(obj.Type()), // address
pos: obj.Pos(),
spec: spec,
}
pkg.values[obj] = g
pkg.Members[name] = g
case *types.Func:
var fs *funcSyntax
synthetic := "loaded from gc object file"
if decl, ok := syntax.(*ast.FuncDecl); ok {
synthetic = ""
fs = &funcSyntax{
go.tools/ssa: add debug information for all ast.Idents. This CL adds three new functions to determine the SSA Value for a given syntactic var, func or const object: Program.{Const,Func,Var}Value. Since constants and functions are immutable, the first two only need a types.Object; but each distinct reference to a var may return a distinct Value, so the third requires an ast.Ident parameter too. Debug information for local vars is encoded in the instruction stream in the form of DebugRef instructions, which are a no-op but relate their operand to a particular ident in the AST. The beauty of this approach is that it naturally stays consistent during optimisation passes (e.g. lifting) without additional bookkeeping. DebugRef instructions are only generated if the DebugMode builder flag is set; I plan to make the policy more fine- grained (per function). DebugRef instructions are inserted for: - expr(Ident) for rvalue idents - address.store() for idents that update an lvalue - address.address() for idents that take address of lvalue (this new method replaces all uses of lval.(address).addr) - expr() for all constant expressions - local ValueSpecs with implicit zero initialization (no RHS) (this case doesn't call store() or address()) To ensure we don't forget to emit debug info for uses of Idents, we must use the lvalue mechanism consistently. (Previously, many simple cases had effectively inlined these functions.) Similarly setCallFunc no longer inlines expr(Ident). Also: - Program.Value() has been inlined & specialized. - Program.Package() has moved nearer the new lookup functions. - refactoring: funcSyntax has lost paramFields, resultFields; gained funcType, which provides access to both. - add package-level constants to Package.values map. - opt: don't call localValueSpec for constants. (The resulting code is always optimised away.) There are a number of comments asking whether Literals should have positions. Will address in a follow-up. Added tests of all interesting cases. R=gri CC=golang-dev https://golang.org/cl/11259044
2013-07-15 11:56:46 -06:00
functype: decl.Type,
recvField: decl.Recv,
body: decl.Body,
}
}
sig := obj.Type().(*types.Signature)
fn := &Function{
name: name,
object: obj,
Signature: sig,
Synthetic: synthetic,
pos: obj.Pos(), // (iff syntax)
Pkg: pkg,
Prog: pkg.Prog,
syntax: fs,
}
if recv := sig.Recv(); recv == nil {
// Function declaration.
pkg.values[obj] = fn
pkg.Members[name] = fn
} else {
// Method declaration.
_, method := namedTypeMethodIndex(
deref(recv.Type()).(*types.Named),
makeId(name, pkg.Object))
pkg.Prog.concreteMethods[method] = fn
}
case *types.Method:
// TODO(adonovan): do something more sensible here?
memberFromObject(pkg, obj.Func, syntax)
default: // (incl. *types.Package)
panic(fmt.Sprintf("unexpected Object type: %T", obj))
}
}
// membersFromDecl populates package pkg with members for each
// typechecker object (var, func, const or type) associated with the
// specified decl.
//
func membersFromDecl(pkg *Package, decl ast.Decl) {
switch decl := decl.(type) {
case *ast.GenDecl: // import, const, type or var
switch decl.Tok {
case token.CONST:
for _, spec := range decl.Specs {
for _, id := range spec.(*ast.ValueSpec).Names {
if !isBlankIdent(id) {
memberFromObject(pkg, pkg.objectOf(id), nil)
}
}
}
case token.VAR:
for _, spec := range decl.Specs {
for _, id := range spec.(*ast.ValueSpec).Names {
if !isBlankIdent(id) {
memberFromObject(pkg, pkg.objectOf(id), spec)
}
}
}
case token.TYPE:
for _, spec := range decl.Specs {
id := spec.(*ast.TypeSpec).Name
if !isBlankIdent(id) {
memberFromObject(pkg, pkg.objectOf(id), nil)
}
}
}
case *ast.FuncDecl:
id := decl.Name
if decl.Recv == nil && id.Name == "init" {
if !pkg.init.pos.IsValid() {
pkg.init.pos = decl.Name.Pos()
pkg.init.Synthetic = ""
}
return // init blocks aren't functions
}
if !isBlankIdent(id) {
memberFromObject(pkg, pkg.objectOf(id), decl)
}
}
}
// createPackage constructs an SSA Package from an error-free
// package described by info, and populates its Members mapping.
//
// The real work of building SSA form for each function is not done
// until a subsequent call to Package.Build().
//
func createPackage(prog *Program, importPath string, info *importer.PackageInfo) {
p := &Package{
Prog: prog,
Members: make(map[string]Member),
values: make(map[types.Object]Value),
Object: info.Pkg,
info: info, // transient (CREATE and BUILD phases)
}
// Add init() function.
p.init = &Function{
name: "init",
Signature: new(types.Signature),
Synthetic: "package initializer",
Pkg: p,
Prog: prog,
}
p.Members[p.init.name] = p.init
// CREATE phase.
// Allocate all package members: vars, funcs and consts and types.
if len(info.Files) > 0 {
// Go source package.
for _, file := range info.Files {
for _, decl := range file.Decls {
membersFromDecl(p, decl)
}
}
} else {
// GC-compiled binary package.
// No code.
// No position information.
scope := p.Object.Scope()
for i, n := 0, scope.NumEntries(); i < n; i++ {
obj := scope.At(i)
if obj, ok := obj.(*types.TypeName); ok {
mset := types.NewMethodSet(obj.Type())
for i, n := 0, mset.Len(); i < n; i++ {
memberFromObject(p, mset.At(i), nil)
}
mset = types.NewMethodSet(types.NewPointer(obj.Type()))
for i, n := 0, mset.Len(); i < n; i++ {
memberFromObject(p, mset.At(i), nil)
}
}
memberFromObject(p, obj, nil)
}
}
// Add initializer guard variable.
initguard := &Global{
Pkg: p,
name: "init$guard",
typ: types.NewPointer(tBool),
}
p.Members[initguard.Name()] = initguard
if prog.mode&LogPackages != 0 {
p.DumpTo(os.Stderr)
}
prog.PackagesByPath[importPath] = p
prog.packages[p.Object] = p
if prog.mode&SanityCheckFunctions != 0 {
sanityCheckPackage(p)
}
}