src/cmd/compile/internal/noder/linker.go - go - Git at Google

 // 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.

 package noder

 import (
 	"internal/pkgbits"
 	"io"

 	"cmd/compile/internal/base"
 	"cmd/compile/internal/ir"
 	"cmd/compile/internal/reflectdata"
 	"cmd/compile/internal/types"
 	"cmd/internal/goobj"
 	"cmd/internal/obj"
 )

 // This file implements the unified IR linker, which combines the
 // local package's stub data with imported package data to produce a
 // complete export data file. It also rewrites the compiler's
 // extension data sections based on the results of compilation (e.g.,
 // the function inlining cost and linker symbol index assignments).
 //
 // TODO(mdempsky): Using the name "linker" here is confusing, because
 // readers are likely to mistake references to it for cmd/link. But
 // there's a shortage of good names for "something that combines
 // multiple parts into a cohesive whole"... e.g., "assembler" and
 // "compiler" are also already taken.

 // TODO(mdempsky): Should linker go into pkgbits? Probably the
 // 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

 	pkgs   map[string]pkgbits.Index
 	decls  map[*types.Sym]pkgbits.Index
 	bodies 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 {
 		rent.Idx = l.relocIdx(pr, rent.Kind, rent.Idx)
 		res[i] = rent
 	}
 	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)

 	absIdx := pr.AbsIdx(k, idx)

 	if newidx := pr.newindex[absIdx]; newidx != 0 {
 		return ^newidx
 	}

 	var newidx pkgbits.Index
 	switch k {
 	case pkgbits.RelocString:
 		newidx = l.relocString(pr, idx)
 	case pkgbits.RelocPkg:
 		newidx = l.relocPkg(pr, idx)
 	case pkgbits.RelocObj:
 		newidx = l.relocObj(pr, idx)

 	default:
 		// Generic relocations.
 		//
 		// TODO(mdempsky): Deduplicate more sections? In fact, I think
 		// every section could be deduplicated. This would also be easier
 		// if we do external relocations.

 		w := l.pw.NewEncoderRaw(k)
 		l.relocCommon(pr, &w, k, idx)
 		newidx = w.Idx
 	}

 	pr.newindex[absIdx] = ^newidx

 	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)

 	if newidx, ok := l.pkgs[path]; ok {
 		return newidx
 	}

 	r := pr.NewDecoder(pkgbits.RelocPkg, idx, pkgbits.SyncPkgDef)
 	w := l.pw.NewEncoder(pkgbits.RelocPkg, pkgbits.SyncPkgDef)
 	l.pkgs[path] = w.Idx

 	// TODO(mdempsky): We end up leaving an empty string reference here
 	// from when the package was originally written as "". Probably not
 	// a big deal, but a little annoying. Maybe relocating
 	// cross-references in place is the way to go after all.
 	w.Relocs = l.relocAll(pr, r.Relocs)

 	_ = r.String() // original path
 	w.String(path)

 	io.Copy(&w.Data, &r.Data)

 	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)

 	if newidx, ok := l.decls[sym]; ok {
 		return newidx
 	}

 	if tag == pkgbits.ObjStub && path != "builtin" && path != "unsafe" {
 		pri, ok := objReader[sym]
 		if !ok {
 			base.Fatalf("missing reader for %q.%v", path, name)
 		}
 		assert(ok)

 		pr = pri.pr
 		idx = pri.idx

 		path2, name2, tag2 := pr.PeekObj(idx)
 		sym2 := types.NewPkg(path2, "").Lookup(name2)
 		assert(sym == sym2)
 		assert(tag2 != pkgbits.ObjStub)
 	}

 	w := l.pw.NewEncoderRaw(pkgbits.RelocObj)
 	wext := l.pw.NewEncoderRaw(pkgbits.RelocObjExt)
 	wname := l.pw.NewEncoderRaw(pkgbits.RelocName)
 	wdict := l.pw.NewEncoderRaw(pkgbits.RelocObjDict)

 	l.decls[sym] = w.Idx
 	assert(wext.Idx == w.Idx)
 	assert(wname.Idx == w.Idx)
 	assert(wdict.Idx == w.Idx)

 	l.relocCommon(pr, &w, pkgbits.RelocObj, idx)
 	l.relocCommon(pr, &wname, pkgbits.RelocName, idx)
 	l.relocCommon(pr, &wdict, pkgbits.RelocObjDict, idx)

 	// Generic types and functions won't have definitions, and imported
 	// objects may not either.
 	obj, _ := sym.Def.(*ir.Name)
 	local := sym.Pkg == types.LocalPkg

 	if local && obj != nil {
 		wext.Sync(pkgbits.SyncObject1)
 		switch tag {
 		case pkgbits.ObjFunc:
 			l.relocFuncExt(&wext, obj)
 		case pkgbits.ObjType:
 			l.relocTypeExt(&wext, obj)
 		case pkgbits.ObjVar:
 			l.relocVarExt(&wext, obj)
 		}
 		wext.Flush()
 	} else {
 		l.relocCommon(pr, &wext, pkgbits.RelocObjExt, idx)
 	}

 	// Check if we need to export the inline bodies for functions and
 	// methods.
 	if obj != nil {
 		if obj.Op() == ir.ONAME && obj.Class == ir.PFUNC {
 			l.exportBody(obj, local)
 		}

 		if obj.Op() == ir.OTYPE {
 			if typ := obj.Type(); !typ.IsInterface() {
 				for _, method := range typ.Methods().Slice() {
 					l.exportBody(method.Nname.(*ir.Name), local)
 				}
 			}
 		}
 	}

 	return w.Idx
 }

 // exportBody exports the given function or method's body, if
 // appropriate. local indicates whether it's a local function or
 // method available on a locally declared type. (Due to cross-package
 // type aliases, a method may be imported, but still available on a
 // locally declared type.)
 func (l *linker) exportBody(obj *ir.Name, local bool) {
 	assert(obj.Op() == ir.ONAME && obj.Class == ir.PFUNC)

 	fn := obj.Func
 	if fn.Inl == nil {
 		return // not inlinable anyway
 	}

 	// As a simple heuristic, if the function was declared in this
 	// package or we inlined it somewhere in this package, then we'll
 	// (re)export the function body. This isn't perfect, but seems
 	// reasonable in practice. In particular, it has the nice property
 	// that in the worst case, adding a blank import ensures the
 	// function body is available for inlining.
 	//
 	// TODO(mdempsky): Reimplement the reachable method crawling logic
 	// from typecheck/crawler.go.
 	exportBody := local || fn.Inl.Body != nil
 	if !exportBody {
 		return
 	}

 	sym := obj.Sym()
 	if _, ok := l.bodies[sym]; ok {
 		// Due to type aliases, we might visit methods multiple times.
 		base.AssertfAt(obj.Type().Recv() != nil, obj.Pos(), "expected method: %v", obj)
 		return
 	}

 	pri, ok := bodyReaderFor(fn)
 	assert(ok)
 	l.bodies[sym] = l.relocIdx(pri.pr, pkgbits.RelocBody, pri.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)
 	io.Copy(&w.Data, &r.Data)
 	w.Flush()
 }

 func (l *linker) pragmaFlag(w *pkgbits.Encoder, pragma ir.PragmaFlag) {
 	w.Sync(pkgbits.SyncPragma)
 	w.Int(int(pragma))
 }

 func (l *linker) relocFuncExt(w *pkgbits.Encoder, name *ir.Name) {
 	w.Sync(pkgbits.SyncFuncExt)

 	l.pragmaFlag(w, name.Func.Pragma)
 	l.linkname(w, name)

 	// Relocated extension data.
 	w.Bool(true)

 	// Record definition ABI so cross-ABI calls can be direct.
 	// This is important for the performance of calling some
 	// common functions implemented in assembly (e.g., bytealg).
 	w.Uint64(uint64(name.Func.ABI))

 	// Escape analysis.
 	for _, fs := range &types.RecvsParams {
 		for _, f := range fs(name.Type()).FieldSlice() {
 			w.String(f.Note)
 		}
 	}

 	if inl := name.Func.Inl; w.Bool(inl != nil) {
 		w.Len(int(inl.Cost))
 		w.Bool(inl.CanDelayResults)
 	}

 	w.Sync(pkgbits.SyncEOF)
 }

 func (l *linker) relocTypeExt(w *pkgbits.Encoder, name *ir.Name) {
 	w.Sync(pkgbits.SyncTypeExt)

 	typ := name.Type()

 	l.pragmaFlag(w, name.Pragma())

 	// For type T, export the index of type descriptor symbols of T and *T.
 	l.lsymIdx(w, "", reflectdata.TypeLinksym(typ))
 	l.lsymIdx(w, "", reflectdata.TypeLinksym(typ.PtrTo()))

 	if typ.Kind() != types.TINTER {
 		for _, method := range typ.Methods().Slice() {
 			l.relocFuncExt(w, method.Nname.(*ir.Name))
 		}
 	}
 }

 func (l *linker) relocVarExt(w *pkgbits.Encoder, name *ir.Name) {
 	w.Sync(pkgbits.SyncVarExt)
 	l.linkname(w, name)
 }

 func (l *linker) linkname(w *pkgbits.Encoder, name *ir.Name) {
 	w.Sync(pkgbits.SyncLinkname)

 	linkname := name.Sym().Linkname
 	if !l.lsymIdx(w, linkname, name.Linksym()) {
 		w.String(linkname)
 	}
 }

 func (l *linker) lsymIdx(w *pkgbits.Encoder, linkname string, lsym *obj.LSym) bool {
 	if lsym.PkgIdx > goobj.PkgIdxSelf || (lsym.PkgIdx == goobj.PkgIdxInvalid && !lsym.Indexed()) || linkname != "" {
 		w.Int64(-1)
 		return false
 	}

 	// For a defined symbol, export its index.
 	// For re-exporting an imported symbol, pass its index through.
 	w.Int64(int64(lsym.SymIdx))
 	return true
 }
	// 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.

	package noder

	import (
	"internal/pkgbits"
	"io"

	"cmd/compile/internal/base"
	"cmd/compile/internal/ir"
	"cmd/compile/internal/reflectdata"
	"cmd/compile/internal/types"
	"cmd/internal/goobj"
	"cmd/internal/obj"
	)

	// This file implements the unified IR linker, which combines the
	// local package's stub data with imported package data to produce a
	// complete export data file. It also rewrites the compiler's
	// extension data sections based on the results of compilation (e.g.,
	// the function inlining cost and linker symbol index assignments).
	//
	// TODO(mdempsky): Using the name "linker" here is confusing, because
	// readers are likely to mistake references to it for cmd/link. But
	// there's a shortage of good names for "something that combines
	// multiple parts into a cohesive whole"... e.g., "assembler" and
	// "compiler" are also already taken.

	// TODO(mdempsky): Should linker go into pkgbits? Probably the
	// 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

	pkgs map[string]pkgbits.Index
	decls map[*types.Sym]pkgbits.Index
	bodies 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 {
	rent.Idx = l.relocIdx(pr, rent.Kind, rent.Idx)
	res[i] = rent
	}
	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)

	absIdx := pr.AbsIdx(k, idx)

	if newidx := pr.newindex[absIdx]; newidx != 0 {
	return ^newidx
	}

	var newidx pkgbits.Index
	switch k {
	case pkgbits.RelocString:
	newidx = l.relocString(pr, idx)
	case pkgbits.RelocPkg:
	newidx = l.relocPkg(pr, idx)
	case pkgbits.RelocObj:
	newidx = l.relocObj(pr, idx)

	default:
	// Generic relocations.
	//
	// TODO(mdempsky): Deduplicate more sections? In fact, I think
	// every section could be deduplicated. This would also be easier
	// if we do external relocations.

	w := l.pw.NewEncoderRaw(k)
	l.relocCommon(pr, &w, k, idx)
	newidx = w.Idx
	}

	pr.newindex[absIdx] = ^newidx

	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)

	if newidx, ok := l.pkgs[path]; ok {
	return newidx
	}

	r := pr.NewDecoder(pkgbits.RelocPkg, idx, pkgbits.SyncPkgDef)
	w := l.pw.NewEncoder(pkgbits.RelocPkg, pkgbits.SyncPkgDef)
	l.pkgs[path] = w.Idx

	// TODO(mdempsky): We end up leaving an empty string reference here
	// from when the package was originally written as "". Probably not
	// a big deal, but a little annoying. Maybe relocating
	// cross-references in place is the way to go after all.
	w.Relocs = l.relocAll(pr, r.Relocs)

	_ = r.String() // original path
	w.String(path)

	io.Copy(&w.Data, &r.Data)

	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)

	if newidx, ok := l.decls[sym]; ok {
	return newidx
	}

	if tag == pkgbits.ObjStub && path != "builtin" && path != "unsafe" {
	pri, ok := objReader[sym]
	if !ok {
	base.Fatalf("missing reader for %q.%v", path, name)
	}
	assert(ok)

	pr = pri.pr
	idx = pri.idx

	path2, name2, tag2 := pr.PeekObj(idx)
	sym2 := types.NewPkg(path2, "").Lookup(name2)
	assert(sym == sym2)
	assert(tag2 != pkgbits.ObjStub)
	}

	w := l.pw.NewEncoderRaw(pkgbits.RelocObj)
	wext := l.pw.NewEncoderRaw(pkgbits.RelocObjExt)
	wname := l.pw.NewEncoderRaw(pkgbits.RelocName)
	wdict := l.pw.NewEncoderRaw(pkgbits.RelocObjDict)

	l.decls[sym] = w.Idx
	assert(wext.Idx == w.Idx)
	assert(wname.Idx == w.Idx)
	assert(wdict.Idx == w.Idx)

	l.relocCommon(pr, &w, pkgbits.RelocObj, idx)
	l.relocCommon(pr, &wname, pkgbits.RelocName, idx)
	l.relocCommon(pr, &wdict, pkgbits.RelocObjDict, idx)

	// Generic types and functions won't have definitions, and imported
	// objects may not either.
	obj, _ := sym.Def.(*ir.Name)
	local := sym.Pkg == types.LocalPkg

	if local && obj != nil {
	wext.Sync(pkgbits.SyncObject1)
	switch tag {
	case pkgbits.ObjFunc:
	l.relocFuncExt(&wext, obj)
	case pkgbits.ObjType:
	l.relocTypeExt(&wext, obj)
	case pkgbits.ObjVar:
	l.relocVarExt(&wext, obj)
	}
	wext.Flush()
	} else {
	l.relocCommon(pr, &wext, pkgbits.RelocObjExt, idx)
	}

	// Check if we need to export the inline bodies for functions and
	// methods.
	if obj != nil {
	if obj.Op() == ir.ONAME && obj.Class == ir.PFUNC {
	l.exportBody(obj, local)
	}

	if obj.Op() == ir.OTYPE {
	if typ := obj.Type(); !typ.IsInterface() {
	for _, method := range typ.Methods().Slice() {
	l.exportBody(method.Nname.(*ir.Name), local)
	}
	}
	}
	}

	return w.Idx
	}

	// exportBody exports the given function or method's body, if
	// appropriate. local indicates whether it's a local function or
	// method available on a locally declared type. (Due to cross-package
	// type aliases, a method may be imported, but still available on a
	// locally declared type.)
	func (l linker) exportBody(obj ir.Name, local bool) {
	assert(obj.Op() == ir.ONAME && obj.Class == ir.PFUNC)

	fn := obj.Func
	if fn.Inl == nil {
	return // not inlinable anyway
	}

	// As a simple heuristic, if the function was declared in this
	// package or we inlined it somewhere in this package, then we'll
	// (re)export the function body. This isn't perfect, but seems
	// reasonable in practice. In particular, it has the nice property
	// that in the worst case, adding a blank import ensures the
	// function body is available for inlining.
	//
	// TODO(mdempsky): Reimplement the reachable method crawling logic
	// from typecheck/crawler.go.
	exportBody := local \|\| fn.Inl.Body != nil
	if !exportBody {
	return
	}

	sym := obj.Sym()
	if _, ok := l.bodies[sym]; ok {
	// Due to type aliases, we might visit methods multiple times.
	base.AssertfAt(obj.Type().Recv() != nil, obj.Pos(), "expected method: %v", obj)
	return
	}

	pri, ok := bodyReaderFor(fn)
	assert(ok)
	l.bodies[sym] = l.relocIdx(pri.pr, pkgbits.RelocBody, pri.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)
	io.Copy(&w.Data, &r.Data)
	w.Flush()
	}

	func (l linker) pragmaFlag(w pkgbits.Encoder, pragma ir.PragmaFlag) {
	w.Sync(pkgbits.SyncPragma)
	w.Int(int(pragma))
	}

	func (l linker) relocFuncExt(w pkgbits.Encoder, name *ir.Name) {
	w.Sync(pkgbits.SyncFuncExt)

	l.pragmaFlag(w, name.Func.Pragma)
	l.linkname(w, name)

	// Relocated extension data.
	w.Bool(true)

	// Record definition ABI so cross-ABI calls can be direct.
	// This is important for the performance of calling some
	// common functions implemented in assembly (e.g., bytealg).
	w.Uint64(uint64(name.Func.ABI))

	// Escape analysis.
	for _, fs := range &types.RecvsParams {
	for _, f := range fs(name.Type()).FieldSlice() {
	w.String(f.Note)
	}
	}

	if inl := name.Func.Inl; w.Bool(inl != nil) {
	w.Len(int(inl.Cost))
	w.Bool(inl.CanDelayResults)
	}

	w.Sync(pkgbits.SyncEOF)
	}

	func (l linker) relocTypeExt(w pkgbits.Encoder, name *ir.Name) {
	w.Sync(pkgbits.SyncTypeExt)

	typ := name.Type()

	l.pragmaFlag(w, name.Pragma())

	// For type T, export the index of type descriptor symbols of T and *T.
	l.lsymIdx(w, "", reflectdata.TypeLinksym(typ))
	l.lsymIdx(w, "", reflectdata.TypeLinksym(typ.PtrTo()))

	if typ.Kind() != types.TINTER {
	for _, method := range typ.Methods().Slice() {
	l.relocFuncExt(w, method.Nname.(*ir.Name))
	}
	}
	}

	func (l linker) relocVarExt(w pkgbits.Encoder, name *ir.Name) {
	w.Sync(pkgbits.SyncVarExt)
	l.linkname(w, name)
	}

	func (l linker) linkname(w pkgbits.Encoder, name *ir.Name) {
	w.Sync(pkgbits.SyncLinkname)

	linkname := name.Sym().Linkname
	if !l.lsymIdx(w, linkname, name.Linksym()) {
	w.String(linkname)
	}
	}

	func (l linker) lsymIdx(w pkgbits.Encoder, linkname string, lsym *obj.LSym) bool {
	if lsym.PkgIdx > goobj.PkgIdxSelf \|\| (lsym.PkgIdx == goobj.PkgIdxInvalid && !lsym.Indexed()) \|\| linkname != "" {
	w.Int64(-1)
	return false
	}

	// For a defined symbol, export its index.
	// For re-exporting an imported symbol, pass its index through.
	w.Int64(int64(lsym.SymIdx))
	return true
	}