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mirror of https://github.com/golang/go synced 2024-11-22 22:40:02 -07:00

[dev.unified] cmd/compile: more Unified IR docs and review

This adds more documentation throughout the core Unified IR logic and
removes their UNREVIEWED notices.

Updates #48194.

Change-Id: Iddd30edaee1c6ea8a05a5a7e013480e02be00d29
Reviewed-on: https://go-review.googlesource.com/c/go/+/411917
Auto-Submit: Matthew Dempsky <mdempsky@google.com>
Run-TryBot: Matthew Dempsky <mdempsky@google.com>
Reviewed-by: Cuong Manh Le <cuong.manhle.vn@gmail.com>
Reviewed-by: David Chase <drchase@google.com>
TryBot-Result: Gopher Robot <gobot@golang.org>
This commit is contained in:
Matthew Dempsky 2022-05-24 10:24:05 -07:00 committed by Gopher Robot
parent f73ad3d24d
commit 394ea70cc9
6 changed files with 241 additions and 69 deletions

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@ -1,5 +1,3 @@
// UNREVIEWED
// Copyright 2021 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.
@ -8,6 +6,7 @@ package noder
import "internal/pkgbits"
// A codeStmt distinguishes among statement encodings.
type codeStmt int
func (c codeStmt) Marker() pkgbits.SyncMarker { return pkgbits.SyncStmt1 }
@ -31,6 +30,7 @@ const (
stmtSelect
)
// A codeExpr distinguishes among expression encodings.
type codeExpr int
func (c codeExpr) Marker() pkgbits.SyncMarker { return pkgbits.SyncExpr }
@ -66,6 +66,7 @@ const (
assignExpr
)
// A codeDecl distinguishes among declaration encodings.
type codeDecl int
func (c codeDecl) Marker() pkgbits.SyncMarker { return pkgbits.SyncDecl }

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@ -1,5 +1,3 @@
// UNREVIEWED
// Copyright 2021 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.
@ -34,6 +32,9 @@ import (
// low-level linking details can be moved there, but the logic for
// handling extension data needs to stay in the compiler.
// A linker combines a package's stub export data with any referenced
// elements from imported packages into a single, self-contained
// export data file.
type linker struct {
pw pkgbits.PkgEncoder
@ -41,6 +42,9 @@ type linker struct {
decls map[*types.Sym]pkgbits.Index
}
// relocAll ensures that all elements specified by pr and relocs are
// copied into the output export data file, and returns the
// corresponding indices in the output.
func (l *linker) relocAll(pr *pkgReader, relocs []pkgbits.RelocEnt) []pkgbits.RelocEnt {
res := make([]pkgbits.RelocEnt, len(relocs))
for i, rent := range relocs {
@ -50,6 +54,8 @@ func (l *linker) relocAll(pr *pkgReader, relocs []pkgbits.RelocEnt) []pkgbits.Re
return res
}
// relocIdx ensures a single element is copied into the output export
// data file, and returns the corresponding index in the output.
func (l *linker) relocIdx(pr *pkgReader, k pkgbits.RelocKind, idx pkgbits.Index) pkgbits.Index {
assert(pr != nil)
@ -85,10 +91,19 @@ func (l *linker) relocIdx(pr *pkgReader, k pkgbits.RelocKind, idx pkgbits.Index)
return newidx
}
// relocString copies the specified string from pr into the output
// export data file, deduplicating it against other strings.
func (l *linker) relocString(pr *pkgReader, idx pkgbits.Index) pkgbits.Index {
return l.pw.StringIdx(pr.StringIdx(idx))
}
// relocPkg copies the specified package from pr into the output
// export data file, rewriting its import path to match how it was
// imported.
//
// TODO(mdempsky): Since CL 391014, we already have the compilation
// unit's import path, so there should be no need to rewrite packages
// anymore.
func (l *linker) relocPkg(pr *pkgReader, idx pkgbits.Index) pkgbits.Index {
path := pr.PeekPkgPath(idx)
@ -114,6 +129,9 @@ func (l *linker) relocPkg(pr *pkgReader, idx pkgbits.Index) pkgbits.Index {
return w.Flush()
}
// relocObj copies the specified object from pr into the output export
// data file, rewriting its compiler-private extension data (e.g.,
// adding inlining cost and escape analysis results for functions).
func (l *linker) relocObj(pr *pkgReader, idx pkgbits.Index) pkgbits.Index {
path, name, tag := pr.PeekObj(idx)
sym := types.NewPkg(path, "").Lookup(name)
@ -184,6 +202,8 @@ func (l *linker) relocObj(pr *pkgReader, idx pkgbits.Index) pkgbits.Index {
return w.Idx
}
// relocCommon copies the specified element from pr into w,
// recursively relocating any referenced elements as well.
func (l *linker) relocCommon(pr *pkgReader, w *pkgbits.Encoder, k pkgbits.RelocKind, idx pkgbits.Index) {
r := pr.NewDecoderRaw(k, idx)
w.Relocs = l.relocAll(pr, r.Relocs)

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@ -1,5 +1,3 @@
// UNREVIEWED
// Copyright 2021 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.
@ -12,12 +10,12 @@ import (
"cmd/compile/internal/syntax"
)
// This file defines helper functions useful for satisfying toolstash
// -cmp when compared against the legacy frontend behavior, but can be
// removed after that's no longer a concern.
// typeExprEndPos returns the position that noder would leave base.Pos
// after parsing the given type expression.
//
// Deprecated: This function exists to emulate position semantics from
// Go 1.17, necessary for compatibility with the backend DWARF
// generation logic that assigns variables to their appropriate scope.
func typeExprEndPos(expr0 syntax.Expr) syntax.Pos {
for {
switch expr := expr0.(type) {

View File

@ -1,5 +1,3 @@
// UNREVIEWED
// Copyright 2021 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.
@ -26,15 +24,25 @@ import (
"cmd/internal/src"
)
// This file implements cmd/compile backend's reader for the Unified
// IR export data.
// A pkgReader reads Unified IR export data.
type pkgReader struct {
pkgbits.PkgDecoder
// Indices for encoded things; lazily populated as needed.
//
// Note: Objects (i.e., ir.Names) are lazily instantiated by
// populating their types.Sym.Def; see objReader below.
posBases []*src.PosBase
pkgs []*types.Pkg
typs []*types.Type
// offset for rewriting the given index into the output,
// but bitwise inverted so we can detect if we're missing the entry or not.
// offset for rewriting the given (absolute!) index into the output,
// but bitwise inverted so we can detect if we're missing the entry
// or not.
newindex []pkgbits.Index
}
@ -50,6 +58,8 @@ func newPkgReader(pr pkgbits.PkgDecoder) *pkgReader {
}
}
// A pkgReaderIndex compactly identifies an index (and its
// corresponding dictionary) within a package's export data.
type pkgReaderIndex struct {
pr *pkgReader
idx pkgbits.Index
@ -69,6 +79,7 @@ func (pr *pkgReader) newReader(k pkgbits.RelocKind, idx pkgbits.Index, marker pk
}
}
// A writer provides APIs for reading an individual element.
type reader struct {
pkgbits.Decoder
@ -162,6 +173,7 @@ func setValue(name *ir.Name, val constant.Value) {
// @@@ Positions
// pos reads a position from the bitstream.
func (r *reader) pos() src.XPos {
return base.Ctxt.PosTable.XPos(r.pos0())
}
@ -178,10 +190,13 @@ func (r *reader) pos0() src.Pos {
return src.MakePos(posBase, line, col)
}
// posBase reads a position base from the bitstream.
func (r *reader) posBase() *src.PosBase {
return r.inlPosBase(r.p.posBaseIdx(r.Reloc(pkgbits.RelocPosBase)))
}
// posBaseIdx returns the specified position base, reading it first if
// needed.
func (pr *pkgReader) posBaseIdx(idx pkgbits.Index) *src.PosBase {
if b := pr.posBases[idx]; b != nil {
return b
@ -222,6 +237,7 @@ func (pr *pkgReader) posBaseIdx(idx pkgbits.Index) *src.PosBase {
return b
}
// TODO(mdempsky): Document this.
func (r *reader) inlPosBase(oldBase *src.PosBase) *src.PosBase {
if r.inlCall == nil {
return oldBase
@ -236,36 +252,23 @@ func (r *reader) inlPosBase(oldBase *src.PosBase) *src.PosBase {
return newBase
}
// TODO(mdempsky): Document this.
func (r *reader) updatePos(xpos src.XPos) src.XPos {
pos := base.Ctxt.PosTable.Pos(xpos)
pos.SetBase(r.inlPosBase(pos.Base()))
return base.Ctxt.PosTable.XPos(pos)
}
func (r *reader) origPos(xpos src.XPos) src.XPos {
if r.inlCall == nil {
return xpos
}
pos := base.Ctxt.PosTable.Pos(xpos)
for old, new := range r.inlPosBases {
if pos.Base() == new {
pos.SetBase(old)
return base.Ctxt.PosTable.XPos(pos)
}
}
base.FatalfAt(xpos, "pos base missing from inlPosBases")
panic("unreachable")
}
// @@@ Packages
// pkg reads a package reference from the bitstream.
func (r *reader) pkg() *types.Pkg {
r.Sync(pkgbits.SyncPkg)
return r.p.pkgIdx(r.Reloc(pkgbits.RelocPkg))
}
// pkgIdx returns the specified package from the export data, reading
// it first if needed.
func (pr *pkgReader) pkgIdx(idx pkgbits.Index) *types.Pkg {
if pkg := pr.pkgs[idx]; pkg != nil {
return pkg
@ -276,6 +279,7 @@ func (pr *pkgReader) pkgIdx(idx pkgbits.Index) *types.Pkg {
return pkg
}
// doPkg reads a package definition from the bitstream.
func (r *reader) doPkg() *types.Pkg {
path := r.String()
switch path {
@ -530,8 +534,12 @@ func (r *reader) param() (*types.Pkg, *types.Field) {
// @@@ Objects
// objReader maps qualified identifiers (represented as *types.Sym) to
// a pkgReader and corresponding index that can be used for reading
// that object's definition.
var objReader = map[*types.Sym]pkgReaderIndex{}
// obj reads an instantiated object reference from the bitstream.
func (r *reader) obj() ir.Node {
r.Sync(pkgbits.SyncObject)
@ -567,6 +575,8 @@ func (r *reader) obj() ir.Node {
return r.p.objIdx(idx, implicits, explicits)
}
// objIdx returns the specified object from the bitstream,
// instantiated with the given type arguments, if any.
func (pr *pkgReader) objIdx(idx pkgbits.Index, implicits, explicits []*types.Type) ir.Node {
rname := pr.newReader(pkgbits.RelocName, idx, pkgbits.SyncObject1)
_, sym := rname.qualifiedIdent()
@ -707,6 +717,7 @@ func (r *reader) mangle(sym *types.Sym) *types.Sym {
return sym.Pkg.Lookup(buf.String())
}
// objDictIdx reads and returns the specified object dictionary.
func (pr *pkgReader) objDictIdx(sym *types.Sym, idx pkgbits.Index, implicits, explicits []*types.Type) *readerDict {
r := pr.newReader(pkgbits.RelocObjDict, idx, pkgbits.SyncObject1)
@ -955,6 +966,8 @@ var bodyReader = map[*ir.Func]pkgReaderIndex{}
// constructed.
var todoBodies []*ir.Func
// addBody reads a function body reference from the element bitstream,
// and associates it with fn.
func (r *reader) addBody(fn *ir.Func) {
pri := pkgReaderIndex{r.p, r.Reloc(pkgbits.RelocBody), r.dict}
bodyReader[fn] = pri
@ -978,6 +991,8 @@ func (pri pkgReaderIndex) funcBody(fn *ir.Func) {
r.funcBody(fn)
}
// funcBody reads a function body definition from the element
// bitstream, and populates fn with it.
func (r *reader) funcBody(fn *ir.Func) {
r.curfn = fn
r.closureVars = fn.ClosureVars
@ -1995,6 +2010,8 @@ func (r *reader) pkgObjs(target *ir.Package) []*ir.Name {
var inlgen = 0
// InlineCall implements inline.NewInline by re-reading the function
// body from its Unified IR export data.
func InlineCall(call *ir.CallExpr, fn *ir.Func, inlIndex int) *ir.InlinedCallExpr {
// TODO(mdempsky): Turn callerfn into an explicit parameter.
callerfn := ir.CurFunc
@ -2281,18 +2298,21 @@ func (r *reader) needWrapper(typ *types.Type) {
}
}
// importedDef reports whether r is reading from an imported and
// non-generic element.
//
// If a type was found in an imported package, then we can assume that
// package (or one of its transitive dependencies) already generated
// method wrappers for it.
//
// Exception: If we're instantiating an imported generic type or
// function, we might be instantiating it with type arguments not
// previously seen before.
//
// TODO(mdempsky): Distinguish when a generic function or type was
// instantiated in an imported package so that we can add types to
// haveWrapperTypes instead.
func (r *reader) importedDef() bool {
// If a type was found in an imported package, then we can assume
// that package (or one of its transitive dependencies) already
// generated method wrappers for it.
//
// Exception: If we're instantiating an imported generic type or
// function, we might be instantiating it with type arguments not
// previously seen before.
//
// TODO(mdempsky): Distinguish when a generic function or type was
// instantiated in an imported package so that we can add types to
// haveWrapperTypes instead.
return r.p != localPkgReader && !r.hasTypeParams()
}

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@ -1,5 +1,3 @@
// UNREVIEWED
// Copyright 2021 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.
@ -226,6 +224,8 @@ func freePackage(pkg *types2.Package) {
base.Fatalf("package never finalized")
}
// readPackage reads package export data from pr to populate
// importpkg.
func readPackage(pr *pkgReader, importpkg *types.Pkg) {
r := pr.newReader(pkgbits.RelocMeta, pkgbits.PublicRootIdx, pkgbits.SyncPublic)
@ -252,6 +252,8 @@ func readPackage(pr *pkgReader, importpkg *types.Pkg) {
}
}
// writeUnifiedExport writes to `out` the finalized, self-contained
// Unified IR export data file for the current compilation unit.
func writeUnifiedExport(out io.Writer) {
l := linker{
pw: pkgbits.NewPkgEncoder(base.Debug.SyncFrames),

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@ -1,5 +1,3 @@
// UNREVIEWED
// Copyright 2021 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.
@ -16,6 +14,45 @@ import (
"cmd/compile/internal/types2"
)
// This file implements the Unified IR package writer and defines the
// Unified IR export data format.
//
// Low-level coding details (e.g., byte-encoding of individual
// primitive values, or handling element bitstreams and
// cross-references) are handled by internal/pkgbits, so here we only
// concern ourselves with higher-level worries like mapping Go
// language constructs into elements.
// There are two central types in the writing process: the "writer"
// type handles writing out individual elements, while the "pkgWriter"
// type keeps track of which elements have already been created.
//
// For each sort of "thing" (e.g., position, package, object, type)
// that can be written into the export data, there are generally
// several methods that work together:
//
// - writer.thing handles writing out a *use* of a thing, which often
// means writing a relocation to that thing's encoded index.
//
// - pkgWriter.thingIdx handles reserving an index for a thing, and
// writing out any elements needed for the thing.
//
// - writer.doThing handles writing out the *definition* of a thing,
// which in general is a mix of low-level coding primitives (e.g.,
// ints and strings) or uses of other things.
//
// A design goal of Unified IR is to have a single, canonical writer
// implementation, but multiple reader implementations each tailored
// to their respective needs. For example, within cmd/compile's own
// backend, inlining is implemented largely by just re-running the
// function body reading code.
// TODO(mdempsky): Add an importer for Unified IR to the x/tools repo,
// and better document the file format boundary between public and
// private data.
// A pkgWriter constructs Unified IR export data from the results of
// running the types2 type checker on a Go compilation unit.
type pkgWriter struct {
pkgbits.PkgEncoder
@ -23,18 +60,29 @@ type pkgWriter struct {
curpkg *types2.Package
info *types2.Info
// Indices for previously written syntax and types2 things.
posBasesIdx map[*syntax.PosBase]pkgbits.Index
pkgsIdx map[*types2.Package]pkgbits.Index
typsIdx map[types2.Type]pkgbits.Index
globalsIdx map[types2.Object]pkgbits.Index
objsIdx map[types2.Object]pkgbits.Index
// Maps from types2.Objects back to their syntax.Decl.
funDecls map[*types2.Func]*syntax.FuncDecl
typDecls map[*types2.TypeName]typeDeclGen
linknames map[types2.Object]string
// linknames maps package-scope objects to their linker symbol name,
// if specified by a //go:linkname directive.
linknames map[types2.Object]string
// cgoPragmas accumulates any //go:cgo_* pragmas that need to be
// passed through to cmd/link.
cgoPragmas [][]string
}
// newPkgWriter returns an initialized pkgWriter for the specified
// package.
func newPkgWriter(m posMap, pkg *types2.Package, info *types2.Info) *pkgWriter {
return &pkgWriter{
PkgEncoder: pkgbits.NewPkgEncoder(base.Debug.SyncFrames),
@ -43,9 +91,9 @@ func newPkgWriter(m posMap, pkg *types2.Package, info *types2.Info) *pkgWriter {
curpkg: pkg,
info: info,
pkgsIdx: make(map[*types2.Package]pkgbits.Index),
globalsIdx: make(map[types2.Object]pkgbits.Index),
typsIdx: make(map[types2.Type]pkgbits.Index),
pkgsIdx: make(map[*types2.Package]pkgbits.Index),
objsIdx: make(map[types2.Object]pkgbits.Index),
typsIdx: make(map[types2.Type]pkgbits.Index),
posBasesIdx: make(map[*syntax.PosBase]pkgbits.Index),
@ -56,18 +104,23 @@ func newPkgWriter(m posMap, pkg *types2.Package, info *types2.Info) *pkgWriter {
}
}
// errorf reports a user error about thing p.
func (pw *pkgWriter) errorf(p poser, msg string, args ...interface{}) {
base.ErrorfAt(pw.m.pos(p), msg, args...)
}
// fatalf reports an internal compiler error about thing p.
func (pw *pkgWriter) fatalf(p poser, msg string, args ...interface{}) {
base.FatalfAt(pw.m.pos(p), msg, args...)
}
// unexpected reports a fatal error about a thing of unexpected
// dynamic type.
func (pw *pkgWriter) unexpected(what string, p poser) {
pw.fatalf(p, "unexpected %s: %v (%T)", what, p, p)
}
// A writer provides APIs for writing out an individual element.
type writer struct {
p *pkgWriter
@ -77,13 +130,19 @@ type writer struct {
// scope closes, and then maybe we can just use the same map for
// storing the TypeParams too (as their TypeName instead).
// variables declared within this function
// localsIdx tracks any local variables declared within this
// function body. It's unused for writing out non-body things.
localsIdx map[*types2.Var]int
closureVars []posObj
closureVarsIdx map[*types2.Var]int
// closureVars tracks any free variables that are referenced by this
// function body. It's unused for writing out non-body things.
closureVars []posVar
closureVarsIdx map[*types2.Var]int // index of previously seen free variables
dict *writerDict
dict *writerDict
// derived tracks whether the type being written out references any
// type parameters. It's unused for writing non-type things.
derived bool
}
@ -128,16 +187,25 @@ type typeInfo struct {
derived bool
}
// An objInfo represents a reference to an encoded, instantiated (if
// applicable) Go object.
type objInfo struct {
idx pkgbits.Index // index for the generic function declaration
explicits []typeInfo // info for the type arguments
}
// An itabInfo represents a reference to an encoded itab entry (i.e.,
// a non-empty interface type along with a concrete type that
// implements that interface).
//
// itabInfo is only used for
type itabInfo struct {
typIdx pkgbits.Index // always a derived type index
iface typeInfo // always a non-empty interface type
}
// anyDerived reports whether any of info's explicit type arguments
// are derived types.
func (info objInfo) anyDerived() bool {
for _, explicit := range info.explicits {
if explicit.derived {
@ -147,6 +215,8 @@ func (info objInfo) anyDerived() bool {
return false
}
// equals reports whether info and other represent the same Go object
// (i.e., same base object and identical type arguments, if any).
func (info objInfo) equals(other objInfo) bool {
if info.idx != other.idx {
return false
@ -169,6 +239,7 @@ func (pw *pkgWriter) newWriter(k pkgbits.RelocKind, marker pkgbits.SyncMarker) *
// @@@ Positions
// pos writes the position of p into the element bitstream.
func (w *writer) pos(p poser) {
w.Sync(pkgbits.SyncPos)
pos := p.Pos()
@ -178,17 +249,19 @@ func (w *writer) pos(p poser) {
return
}
// TODO(mdempsky): Delta encoding. Also, if there's a b-side, update
// its position base too (but not vice versa!).
// TODO(mdempsky): Delta encoding.
w.posBase(pos.Base())
w.Uint(pos.Line())
w.Uint(pos.Col())
}
// posBase writes a reference to the given PosBase into the element
// bitstream.
func (w *writer) posBase(b *syntax.PosBase) {
w.Reloc(pkgbits.RelocPosBase, w.p.posBaseIdx(b))
}
// posBaseIdx returns the index for the given PosBase.
func (pw *pkgWriter) posBaseIdx(b *syntax.PosBase) pkgbits.Index {
if idx, ok := pw.posBasesIdx[b]; ok {
return idx
@ -210,11 +283,14 @@ func (pw *pkgWriter) posBaseIdx(b *syntax.PosBase) pkgbits.Index {
// @@@ Packages
// pkg writes a use of the given Package into the element bitstream.
func (w *writer) pkg(pkg *types2.Package) {
w.Sync(pkgbits.SyncPkg)
w.Reloc(pkgbits.RelocPkg, w.p.pkgIdx(pkg))
}
// pkgIdx returns the index for the given package, adding it to the
// package export data if needed.
func (pw *pkgWriter) pkgIdx(pkg *types2.Package) pkgbits.Index {
if idx, ok := pw.pkgsIdx[pkg]; ok {
return idx
@ -256,10 +332,13 @@ func (pw *pkgWriter) pkgIdx(pkg *types2.Package) pkgbits.Index {
var anyTypeName = types2.Universe.Lookup("any").(*types2.TypeName)
// typ writes a use of the given type into the bitstream.
func (w *writer) typ(typ types2.Type) {
w.typInfo(w.p.typIdx(typ, w.dict))
}
// typInfo writes a use of the given type (specified as a typeInfo
// instead) into the bitstream.
func (w *writer) typInfo(info typeInfo) {
w.Sync(pkgbits.SyncType)
if w.Bool(info.derived) {
@ -468,6 +547,11 @@ func (w *writer) param(param *types2.Var) {
// @@@ Objects
// obj writes a use of the given object into the bitstream.
//
// If obj is a generic object, then explicits are the explicit type
// arguments used to instantiate it (i.e., used to substitute the
// object's own declared type parameters).
func (w *writer) obj(obj types2.Object, explicits *types2.TypeList) {
explicitInfos := make([]typeInfo, explicits.Len())
for i := range explicitInfos {
@ -515,8 +599,13 @@ func (w *writer) obj(obj types2.Object, explicits *types2.TypeList) {
}
}
// objIdx returns the index for the given Object, adding it to the
// export data as needed.
func (pw *pkgWriter) objIdx(obj types2.Object) pkgbits.Index {
if idx, ok := pw.globalsIdx[obj]; ok {
// TODO(mdempsky): Validate that obj is a global object (or a local
// defined type, which we hoist to global scope anyway).
if idx, ok := pw.objsIdx[obj]; ok {
return idx
}
@ -530,12 +619,35 @@ func (pw *pkgWriter) objIdx(obj types2.Object) pkgbits.Index {
dict.implicits = decl.implicits
}
// We encode objects into 4 elements across different sections, all
// sharing the same index:
//
// - RelocName has just the object's qualified name (i.e.,
// Object.Pkg and Object.Name) and the CodeObj indicating what
// specific type of Object it is (Var, Func, etc).
//
// - RelocObj has the remaining public details about the object,
// relevant to go/types importers.
//
// - RelocObjExt has additional private details about the object,
// which are only relevant to cmd/compile itself. This is
// separated from RelocObj so that go/types importers are
// unaffected by internal compiler changes.
//
// - RelocObjDict has public details about the object's type
// parameters and derived type's used by the object. This is
// separated to facilitate the eventual introduction of
// shape-based stenciling.
//
// TODO(mdempsky): Re-evaluate whether RelocName still makes sense
// to keep separate from RelocObj.
w := pw.newWriter(pkgbits.RelocObj, pkgbits.SyncObject1)
wext := pw.newWriter(pkgbits.RelocObjExt, pkgbits.SyncObject1)
wname := pw.newWriter(pkgbits.RelocName, pkgbits.SyncObject1)
wdict := pw.newWriter(pkgbits.RelocObjDict, pkgbits.SyncObject1)
pw.globalsIdx[obj] = w.Idx // break cycles
pw.objsIdx[obj] = w.Idx // break cycles
assert(wext.Idx == w.Idx)
assert(wname.Idx == w.Idx)
assert(wdict.Idx == w.Idx)
@ -557,6 +669,8 @@ func (pw *pkgWriter) objIdx(obj types2.Object) pkgbits.Index {
return w.Idx
}
// doObj writes the RelocObj definition for obj to w, and the
// RelocObjExt definition to wext.
func (w *writer) doObj(wext *writer, obj types2.Object) pkgbits.CodeObj {
if obj.Pkg() != w.p.curpkg {
return pkgbits.ObjStub
@ -726,8 +840,8 @@ func (w *writer) qualifiedIdent(obj types2.Object) {
// me a little nervous to try it again.
// localIdent writes the name of a locally declared object (i.e.,
// objects that can only be accessed by name, within the context of a
// particular function).
// objects that can only be accessed by non-qualified name, within the
// context of a particular function).
func (w *writer) localIdent(obj types2.Object) {
assert(!isGlobal(obj))
w.Sync(pkgbits.SyncLocalIdent)
@ -789,7 +903,7 @@ func (w *writer) funcExt(obj *types2.Func) {
}
sig, block := obj.Type().(*types2.Signature), decl.Body
body, closureVars := w.p.bodyIdx(w.p.curpkg, sig, block, w.dict)
body, closureVars := w.p.bodyIdx(sig, block, w.dict)
assert(len(closureVars) == 0)
w.Sync(pkgbits.SyncFuncExt)
@ -831,7 +945,9 @@ func (w *writer) pragmaFlag(p ir.PragmaFlag) {
// @@@ Function bodies
func (pw *pkgWriter) bodyIdx(pkg *types2.Package, sig *types2.Signature, block *syntax.BlockStmt, dict *writerDict) (idx pkgbits.Index, closureVars []posObj) {
// bodyIdx returns the index for the given function body (specified by
// block), adding it to the export data
func (pw *pkgWriter) bodyIdx(sig *types2.Signature, block *syntax.BlockStmt, dict *writerDict) (idx pkgbits.Index, closureVars []posVar) {
w := pw.newWriter(pkgbits.RelocBody, pkgbits.SyncFuncBody)
w.dict = dict
@ -864,6 +980,7 @@ func (w *writer) funcarg(param *types2.Var, result bool) {
}
}
// addLocal records the declaration of a new local variable.
func (w *writer) addLocal(obj *types2.Var) {
w.Sync(pkgbits.SyncAddLocal)
idx := len(w.localsIdx)
@ -876,6 +993,8 @@ func (w *writer) addLocal(obj *types2.Var) {
w.localsIdx[obj] = idx
}
// useLocal writes a reference to the given local or free variable
// into the bitstream.
func (w *writer) useLocal(pos syntax.Pos, obj *types2.Var) {
w.Sync(pkgbits.SyncUseObjLocal)
@ -890,7 +1009,7 @@ func (w *writer) useLocal(pos syntax.Pos, obj *types2.Var) {
w.closureVarsIdx = make(map[*types2.Var]int)
}
idx = len(w.closureVars)
w.closureVars = append(w.closureVars, posObj{pos, obj})
w.closureVars = append(w.closureVars, posVar{pos, obj})
w.closureVarsIdx[obj] = idx
}
w.Len(idx)
@ -913,6 +1032,7 @@ func (w *writer) closeAnotherScope() {
// @@@ Statements
// stmt writes the given statement into the function body bitstream.
func (w *writer) stmt(stmt syntax.Stmt) {
var stmts []syntax.Stmt
if stmt != nil {
@ -1213,6 +1333,7 @@ func (w *writer) optLabel(label *syntax.Name) {
// @@@ Expressions
// expr writes the given expression into the function body bitstream.
func (w *writer) expr(expr syntax.Expr) {
base.Assertf(expr != nil, "missing expression")
@ -1439,7 +1560,7 @@ func (w *writer) funcLit(expr *syntax.FuncLit) {
assert(ok)
sig := tv.Type.(*types2.Signature)
body, closureVars := w.p.bodyIdx(w.p.curpkg, sig, expr.Body, w.dict)
body, closureVars := w.p.bodyIdx(sig, expr.Body, w.dict)
w.Sync(pkgbits.SyncFuncLit)
w.pos(expr)
@ -1448,15 +1569,15 @@ func (w *writer) funcLit(expr *syntax.FuncLit) {
w.Len(len(closureVars))
for _, cv := range closureVars {
w.pos(cv.pos)
w.useLocal(cv.pos, cv.obj)
w.useLocal(cv.pos, cv.var_)
}
w.Reloc(pkgbits.RelocBody, body)
}
type posObj struct {
pos syntax.Pos
obj *types2.Var
type posVar struct {
pos syntax.Pos
var_ *types2.Var
}
func (w *writer) exprList(expr syntax.Expr) {
@ -1509,6 +1630,9 @@ func (w *writer) exprType(iface types2.Type, typ syntax.Expr, nilOK bool) {
w.typInfo(info)
}
// isInterface reports whether typ is known to be an interface type.
// If typ is a type parameter, then isInterface reports an internal
// compiler error instead.
func isInterface(typ types2.Type) bool {
if _, ok := typ.(*types2.TypeParam); ok {
// typ is a type parameter and may be instantiated as either a
@ -1521,6 +1645,7 @@ func isInterface(typ types2.Type) bool {
return ok
}
// op writes an Op into the bitstream.
func (w *writer) op(op ir.Op) {
// TODO(mdempsky): Remove in favor of explicit codes? Would make
// export data more stable against internal refactorings, but low
@ -1561,6 +1686,12 @@ type fileImports struct {
importedEmbed, importedUnsafe bool
}
// declCollector is a visitor type that collects compiler-needed
// information about declarations that types2 doesn't track.
//
// Notably, it maps declared types and functions back to their
// declaration statement, keeps track of implicit type parameters, and
// assigns unique type "generation" numbers to local defined types.
type declCollector struct {
pw *pkgWriter
typegen *int