src/cmd/compile/internal/noder/irgen.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 (
 	"fmt"
 	"os"

 	"cmd/compile/internal/base"
 	"cmd/compile/internal/dwarfgen"
 	"cmd/compile/internal/ir"
 	"cmd/compile/internal/syntax"
 	"cmd/compile/internal/typecheck"
 	"cmd/compile/internal/types"
 	"cmd/compile/internal/types2"
 	"cmd/internal/src"
 )

 // checkFiles configures and runs the types2 checker on the given
 // parsed source files and then returns the result.
 func checkFiles(noders []*noder) (posMap, *types2.Package, *types2.Info) {
 	if base.SyntaxErrors() != 0 {
 		base.ErrorExit()
 	}

 	// setup and syntax error reporting
 	var m posMap
 	files := make([]*syntax.File, len(noders))
 	for i, p := range noders {
 		m.join(&p.posMap)
 		files[i] = p.file
 	}

 	// typechecking
 	ctxt := types2.NewContext()
 	importer := gcimports{
 		ctxt:     ctxt,
 		packages: map[string]*types2.Package{"unsafe": types2.Unsafe},
 	}
 	conf := types2.Config{
 		Context:               ctxt,
 		GoVersion:             base.Flag.Lang,
 		IgnoreLabels:          true, // parser already checked via syntax.CheckBranches mode
 		CompilerErrorMessages: true, // use error strings matching existing compiler errors
 		Error: func(err error) {
 			terr := err.(types2.Error)
 			base.ErrorfAt(m.makeXPos(terr.Pos), "%s", terr.Msg)
 		},
 		Importer: &importer,
 		Sizes:    &gcSizes{},
 	}
 	info := &types2.Info{
 		Types:      make(map[syntax.Expr]types2.TypeAndValue),
 		Defs:       make(map[*syntax.Name]types2.Object),
 		Uses:       make(map[*syntax.Name]types2.Object),
 		Selections: make(map[*syntax.SelectorExpr]*types2.Selection),
 		Implicits:  make(map[syntax.Node]types2.Object),
 		Scopes:     make(map[syntax.Node]*types2.Scope),
 		Instances:  make(map[*syntax.Name]types2.Instance),
 		// expand as needed
 	}

 	pkg, err := conf.Check(base.Ctxt.Pkgpath, files, info)

 	base.ExitIfErrors()
 	if err != nil {
 		base.FatalfAt(src.NoXPos, "conf.Check error: %v", err)
 	}

 	return m, pkg, info
 }

 // check2 type checks a Go package using types2, and then generates IR
 // using the results.
 func check2(noders []*noder) {
 	m, pkg, info := checkFiles(noders)

 	if base.Flag.G < 2 {
 		os.Exit(0)
 	}

 	g := irgen{
 		target: typecheck.Target,
 		self:   pkg,
 		info:   info,
 		posMap: m,
 		objs:   make(map[types2.Object]*ir.Name),
 		typs:   make(map[types2.Type]*types.Type),
 	}
 	g.generate(noders)

 	if base.Flag.G < 3 {
 		os.Exit(0)
 	}
 }

 // dictInfo is the dictionary format for an instantiation of a generic function with
 // particular shapes. shapeParams, derivedTypes, subDictCalls, and itabConvs describe
 // the actual dictionary entries in order, and the remaining fields are other info
 // needed in doing dictionary processing during compilation.
 type dictInfo struct {
 	// Types substituted for the type parameters, which are shape types.
 	shapeParams []*types.Type
 	// All types derived from those typeparams used in the instantiation.
 	derivedTypes []*types.Type
 	// Nodes in the instantiation that requires a subdictionary. Includes
 	// method and function calls (OCALL), function values (OFUNCINST), method
 	// values/expressions (OXDOT).
 	subDictCalls []ir.Node
 	// Nodes in the instantiation that are a conversion from a typeparam/derived
 	// type to a specific interface.
 	itabConvs []ir.Node

 	// Mapping from each shape type that substitutes a type param, to its
 	// type bound (which is also substituted with shapes if it is parameterized)
 	shapeToBound map[*types.Type]*types.Type

 	// For type switches on nonempty interfaces, a map from OTYPE entries of
 	// HasShape type, to the interface type we're switching from.
 	type2switchType map[ir.Node]*types.Type

 	startSubDict  int // Start of dict entries for subdictionaries
 	startItabConv int // Start of dict entries for itab conversions
 	dictLen       int // Total number of entries in dictionary
 }

 // instInfo is information gathered on an shape instantiation of a function.
 type instInfo struct {
 	fun       *ir.Func // The instantiated function (with body)
 	dictParam *ir.Name // The node inside fun that refers to the dictionary param

 	dictInfo *dictInfo
 }

 type irgen struct {
 	target *ir.Package
 	self   *types2.Package
 	info   *types2.Info

 	posMap
 	objs   map[types2.Object]*ir.Name
 	typs   map[types2.Type]*types.Type
 	marker dwarfgen.ScopeMarker

 	// laterFuncs records tasks that need to run after all declarations
 	// are processed.
 	laterFuncs []func()
 	// haveEmbed indicates whether the current node belongs to file that
 	// imports "embed" package.
 	haveEmbed bool

 	// exprStmtOK indicates whether it's safe to generate expressions or
 	// statements yet.
 	exprStmtOK bool

 	// types which we need to finish, by doing g.fillinMethods.
 	typesToFinalize []*typeDelayInfo

 	// True when we are compiling a top-level generic function or method. Use to
 	// avoid adding closures of generic functions/methods to the target.Decls
 	// list.
 	topFuncIsGeneric bool

 	// The context during type/function/method declarations that is used to
 	// uniquely name type parameters. We need unique names for type params so we
 	// can be sure they match up correctly between types2-to-types1 translation
 	// and types1 importing.
 	curDecl string
 }

 // genInst has the information for creating needed instantiations and modifying
 // functions to use instantiations.
 type genInst struct {
 	dnum int // for generating unique dictionary variables

 	// Map from the names of all instantiations to information about the
 	// instantiations.
 	instInfoMap map[*types.Sym]*instInfo

 	// Dictionary syms which we need to finish, by writing out any itabconv
 	// entries.
 	dictSymsToFinalize []*delayInfo

 	// New instantiations created during this round of buildInstantiations().
 	newInsts []ir.Node
 }

 func (g *irgen) later(fn func()) {
 	g.laterFuncs = append(g.laterFuncs, fn)
 }

 type delayInfo struct {
 	gf     *ir.Name
 	targs  []*types.Type
 	sym    *types.Sym
 	off    int
 	isMeth bool
 }

 type typeDelayInfo struct {
 	typ  *types2.Named
 	ntyp *types.Type
 }

 func (g *irgen) generate(noders []*noder) {
 	types.LocalPkg.Name = g.self.Name()
 	types.LocalPkg.Height = g.self.Height()
 	typecheck.TypecheckAllowed = true

 	// Prevent size calculations until we set the underlying type
 	// for all package-block defined types.
 	types.DeferCheckSize()

 	// At this point, types2 has already handled name resolution and
 	// type checking. We just need to map from its object and type
 	// representations to those currently used by the rest of the
 	// compiler. This happens in a few passes.

 	// 1. Process all import declarations. We use the compiler's own
 	// importer for this, rather than types2's gcimporter-derived one,
 	// to handle extensions and inline function bodies correctly.
 	//
 	// Also, we need to do this in a separate pass, because mappings are
 	// instantiated on demand. If we interleaved processing import
 	// declarations with other declarations, it's likely we'd end up
 	// wanting to map an object/type from another source file, but not
 	// yet have the import data it relies on.
 	declLists := make([][]syntax.Decl, len(noders))
 Outer:
 	for i, p := range noders {
 		g.pragmaFlags(p.file.Pragma, ir.GoBuildPragma)
 		for j, decl := range p.file.DeclList {
 			switch decl := decl.(type) {
 			case *syntax.ImportDecl:
 				g.importDecl(p, decl)
 			default:
 				declLists[i] = p.file.DeclList[j:]
 				continue Outer // no more ImportDecls
 			}
 		}
 	}

 	// 2. Process all package-block type declarations. As with imports,
 	// we need to make sure all types are properly instantiated before
 	// trying to map any expressions that utilize them. In particular,
 	// we need to make sure type pragmas are already known (see comment
 	// in irgen.typeDecl).
 	//
 	// We could perhaps instead defer processing of package-block
 	// variable initializers and function bodies, like noder does, but
 	// special-casing just package-block type declarations minimizes the
 	// differences between processing package-block and function-scoped
 	// declarations.
 	for _, declList := range declLists {
 		for _, decl := range declList {
 			switch decl := decl.(type) {
 			case *syntax.TypeDecl:
 				g.typeDecl((*ir.Nodes)(&g.target.Decls), decl)
 			}
 		}
 	}
 	types.ResumeCheckSize()

 	// 3. Process all remaining declarations.
 	for i, declList := range declLists {
 		old := g.haveEmbed
 		g.haveEmbed = noders[i].importedEmbed
 		g.decls((*ir.Nodes)(&g.target.Decls), declList)
 		g.haveEmbed = old
 	}
 	g.exprStmtOK = true

 	// 4. Run any "later" tasks. Avoid using 'range' so that tasks can
 	// recursively queue further tasks. (Not currently utilized though.)
 	for len(g.laterFuncs) > 0 {
 		fn := g.laterFuncs[0]
 		g.laterFuncs = g.laterFuncs[1:]
 		fn()
 	}

 	if base.Flag.W > 1 {
 		for _, n := range g.target.Decls {
 			s := fmt.Sprintf("\nafter noder2 %v", n)
 			ir.Dump(s, n)
 		}
 	}

 	for _, p := range noders {
 		// Process linkname and cgo pragmas.
 		p.processPragmas()

 		// Double check for any type-checking inconsistencies. This can be
 		// removed once we're confident in IR generation results.
 		syntax.Crawl(p.file, func(n syntax.Node) bool {
 			g.validate(n)
 			return false
 		})
 	}

 	if base.Flag.Complete {
 		for _, n := range g.target.Decls {
 			if fn, ok := n.(*ir.Func); ok {
 				if fn.Body == nil && fn.Nname.Sym().Linkname == "" {
 					base.ErrorfAt(fn.Pos(), "missing function body")
 				}
 			}
 		}
 	}

 	// Check for unusual case where noder2 encounters a type error that types2
 	// doesn't check for (e.g. notinheap incompatibility).
 	base.ExitIfErrors()

 	typecheck.DeclareUniverse()

 	// Create any needed instantiations of generic functions and transform
 	// existing and new functions to use those instantiations.
 	BuildInstantiations(true)

 	// Remove all generic functions from g.target.Decl, since they have been
 	// used for stenciling, but don't compile. Generic functions will already
 	// have been marked for export as appropriate.
 	j := 0
 	for i, decl := range g.target.Decls {
 		if decl.Op() != ir.ODCLFUNC || !decl.Type().HasTParam() {
 			g.target.Decls[j] = g.target.Decls[i]
 			j++
 		}
 	}
 	g.target.Decls = g.target.Decls[:j]

 	base.Assertf(len(g.laterFuncs) == 0, "still have %d later funcs", len(g.laterFuncs))
 }

 func (g *irgen) unhandled(what string, p poser) {
 	base.FatalfAt(g.pos(p), "unhandled %s: %T", what, p)
 	panic("unreachable")
 }

 // delayTransform returns true if we should delay all transforms, because we are
 // creating the nodes for a generic function/method.
 func (g *irgen) delayTransform() bool {
 	return g.topFuncIsGeneric
 }
	// 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 (
	"fmt"
	"os"

	"cmd/compile/internal/base"
	"cmd/compile/internal/dwarfgen"
	"cmd/compile/internal/ir"
	"cmd/compile/internal/syntax"
	"cmd/compile/internal/typecheck"
	"cmd/compile/internal/types"
	"cmd/compile/internal/types2"
	"cmd/internal/src"
	)

	// checkFiles configures and runs the types2 checker on the given
	// parsed source files and then returns the result.
	func checkFiles(noders []noder) (posMap, types2.Package, *types2.Info) {
	if base.SyntaxErrors() != 0 {
	base.ErrorExit()
	}

	// setup and syntax error reporting
	var m posMap
	files := make([]*syntax.File, len(noders))
	for i, p := range noders {
	m.join(&p.posMap)
	files[i] = p.file
	}

	// typechecking
	ctxt := types2.NewContext()
	importer := gcimports{
	ctxt: ctxt,
	packages: map[string]*types2.Package{"unsafe": types2.Unsafe},
	}
	conf := types2.Config{
	Context: ctxt,
	GoVersion: base.Flag.Lang,
	IgnoreLabels: true, // parser already checked via syntax.CheckBranches mode
	CompilerErrorMessages: true, // use error strings matching existing compiler errors
	Error: func(err error) {
	terr := err.(types2.Error)
	base.ErrorfAt(m.makeXPos(terr.Pos), "%s", terr.Msg)
	},
	Importer: &importer,
	Sizes: &gcSizes{},
	}
	info := &types2.Info{
	Types: make(map[syntax.Expr]types2.TypeAndValue),
	Defs: make(map[*syntax.Name]types2.Object),
	Uses: make(map[*syntax.Name]types2.Object),
	Selections: make(map[syntax.SelectorExpr]types2.Selection),
	Implicits: make(map[syntax.Node]types2.Object),
	Scopes: make(map[syntax.Node]*types2.Scope),
	Instances: make(map[*syntax.Name]types2.Instance),
	// expand as needed
	}

	pkg, err := conf.Check(base.Ctxt.Pkgpath, files, info)

	base.ExitIfErrors()
	if err != nil {
	base.FatalfAt(src.NoXPos, "conf.Check error: %v", err)
	}

	return m, pkg, info
	}

	// check2 type checks a Go package using types2, and then generates IR
	// using the results.
	func check2(noders []*noder) {
	m, pkg, info := checkFiles(noders)

	if base.Flag.G < 2 {
	os.Exit(0)
	}

	g := irgen{
	target: typecheck.Target,
	self: pkg,
	info: info,
	posMap: m,
	objs: make(map[types2.Object]*ir.Name),
	typs: make(map[types2.Type]*types.Type),
	}
	g.generate(noders)

	if base.Flag.G < 3 {
	os.Exit(0)
	}
	}

	// dictInfo is the dictionary format for an instantiation of a generic function with
	// particular shapes. shapeParams, derivedTypes, subDictCalls, and itabConvs describe
	// the actual dictionary entries in order, and the remaining fields are other info
	// needed in doing dictionary processing during compilation.
	type dictInfo struct {
	// Types substituted for the type parameters, which are shape types.
	shapeParams []*types.Type
	// All types derived from those typeparams used in the instantiation.
	derivedTypes []*types.Type
	// Nodes in the instantiation that requires a subdictionary. Includes
	// method and function calls (OCALL), function values (OFUNCINST), method
	// values/expressions (OXDOT).
	subDictCalls []ir.Node
	// Nodes in the instantiation that are a conversion from a typeparam/derived
	// type to a specific interface.
	itabConvs []ir.Node

	// Mapping from each shape type that substitutes a type param, to its
	// type bound (which is also substituted with shapes if it is parameterized)
	shapeToBound map[types.Type]types.Type

	// For type switches on nonempty interfaces, a map from OTYPE entries of
	// HasShape type, to the interface type we're switching from.
	type2switchType map[ir.Node]*types.Type

	startSubDict int // Start of dict entries for subdictionaries
	startItabConv int // Start of dict entries for itab conversions
	dictLen int // Total number of entries in dictionary
	}

	// instInfo is information gathered on an shape instantiation of a function.
	type instInfo struct {
	fun *ir.Func // The instantiated function (with body)
	dictParam *ir.Name // The node inside fun that refers to the dictionary param

	dictInfo *dictInfo
	}

	type irgen struct {
	target *ir.Package
	self *types2.Package
	info *types2.Info

	posMap
	objs map[types2.Object]*ir.Name
	typs map[types2.Type]*types.Type
	marker dwarfgen.ScopeMarker

	// laterFuncs records tasks that need to run after all declarations
	// are processed.
	laterFuncs []func()
	// haveEmbed indicates whether the current node belongs to file that
	// imports "embed" package.
	haveEmbed bool

	// exprStmtOK indicates whether it's safe to generate expressions or
	// statements yet.
	exprStmtOK bool

	// types which we need to finish, by doing g.fillinMethods.
	typesToFinalize []*typeDelayInfo

	// True when we are compiling a top-level generic function or method. Use to
	// avoid adding closures of generic functions/methods to the target.Decls
	// list.
	topFuncIsGeneric bool

	// The context during type/function/method declarations that is used to
	// uniquely name type parameters. We need unique names for type params so we
	// can be sure they match up correctly between types2-to-types1 translation
	// and types1 importing.
	curDecl string
	}

	// genInst has the information for creating needed instantiations and modifying
	// functions to use instantiations.
	type genInst struct {
	dnum int // for generating unique dictionary variables

	// Map from the names of all instantiations to information about the
	// instantiations.
	instInfoMap map[types.Sym]instInfo

	// Dictionary syms which we need to finish, by writing out any itabconv
	// entries.
	dictSymsToFinalize []*delayInfo

	// New instantiations created during this round of buildInstantiations().
	newInsts []ir.Node
	}

	func (g *irgen) later(fn func()) {
	g.laterFuncs = append(g.laterFuncs, fn)
	}

	type delayInfo struct {
	gf *ir.Name
	targs []*types.Type
	sym *types.Sym
	off int
	isMeth bool
	}

	type typeDelayInfo struct {
	typ *types2.Named
	ntyp *types.Type
	}

	func (g irgen) generate(noders []noder) {
	types.LocalPkg.Name = g.self.Name()
	types.LocalPkg.Height = g.self.Height()
	typecheck.TypecheckAllowed = true

	// Prevent size calculations until we set the underlying type
	// for all package-block defined types.
	types.DeferCheckSize()

	// At this point, types2 has already handled name resolution and
	// type checking. We just need to map from its object and type
	// representations to those currently used by the rest of the
	// compiler. This happens in a few passes.

	// 1. Process all import declarations. We use the compiler's own
	// importer for this, rather than types2's gcimporter-derived one,
	// to handle extensions and inline function bodies correctly.
	//
	// Also, we need to do this in a separate pass, because mappings are
	// instantiated on demand. If we interleaved processing import
	// declarations with other declarations, it's likely we'd end up
	// wanting to map an object/type from another source file, but not
	// yet have the import data it relies on.
	declLists := make([][]syntax.Decl, len(noders))
	Outer:
	for i, p := range noders {
	g.pragmaFlags(p.file.Pragma, ir.GoBuildPragma)
	for j, decl := range p.file.DeclList {
	switch decl := decl.(type) {
	case *syntax.ImportDecl:
	g.importDecl(p, decl)
	default:
	declLists[i] = p.file.DeclList[j:]
	continue Outer // no more ImportDecls
	}
	}
	}

	// 2. Process all package-block type declarations. As with imports,
	// we need to make sure all types are properly instantiated before
	// trying to map any expressions that utilize them. In particular,
	// we need to make sure type pragmas are already known (see comment
	// in irgen.typeDecl).
	//
	// We could perhaps instead defer processing of package-block
	// variable initializers and function bodies, like noder does, but
	// special-casing just package-block type declarations minimizes the
	// differences between processing package-block and function-scoped
	// declarations.
	for _, declList := range declLists {
	for _, decl := range declList {
	switch decl := decl.(type) {
	case *syntax.TypeDecl:
	g.typeDecl((*ir.Nodes)(&g.target.Decls), decl)
	}
	}
	}
	types.ResumeCheckSize()

	// 3. Process all remaining declarations.
	for i, declList := range declLists {
	old := g.haveEmbed
	g.haveEmbed = noders[i].importedEmbed
	g.decls((*ir.Nodes)(&g.target.Decls), declList)
	g.haveEmbed = old
	}
	g.exprStmtOK = true

	// 4. Run any "later" tasks. Avoid using 'range' so that tasks can
	// recursively queue further tasks. (Not currently utilized though.)
	for len(g.laterFuncs) > 0 {
	fn := g.laterFuncs[0]
	g.laterFuncs = g.laterFuncs[1:]
	fn()
	}

	if base.Flag.W > 1 {
	for _, n := range g.target.Decls {
	s := fmt.Sprintf("\nafter noder2 %v", n)
	ir.Dump(s, n)
	}
	}

	for _, p := range noders {
	// Process linkname and cgo pragmas.
	p.processPragmas()

	// Double check for any type-checking inconsistencies. This can be
	// removed once we're confident in IR generation results.
	syntax.Crawl(p.file, func(n syntax.Node) bool {
	g.validate(n)
	return false
	})
	}

	if base.Flag.Complete {
	for _, n := range g.target.Decls {
	if fn, ok := n.(*ir.Func); ok {
	if fn.Body == nil && fn.Nname.Sym().Linkname == "" {
	base.ErrorfAt(fn.Pos(), "missing function body")
	}
	}
	}
	}

	// Check for unusual case where noder2 encounters a type error that types2
	// doesn't check for (e.g. notinheap incompatibility).
	base.ExitIfErrors()

	typecheck.DeclareUniverse()

	// Create any needed instantiations of generic functions and transform
	// existing and new functions to use those instantiations.
	BuildInstantiations(true)

	// Remove all generic functions from g.target.Decl, since they have been
	// used for stenciling, but don't compile. Generic functions will already
	// have been marked for export as appropriate.
	j := 0
	for i, decl := range g.target.Decls {
	if decl.Op() != ir.ODCLFUNC \|\| !decl.Type().HasTParam() {
	g.target.Decls[j] = g.target.Decls[i]
	j++
	}
	}
	g.target.Decls = g.target.Decls[:j]

	base.Assertf(len(g.laterFuncs) == 0, "still have %d later funcs", len(g.laterFuncs))
	}

	func (g *irgen) unhandled(what string, p poser) {
	base.FatalfAt(g.pos(p), "unhandled %s: %T", what, p)
	panic("unreachable")
	}

	// delayTransform returns true if we should delay all transforms, because we are
	// creating the nodes for a generic function/method.
	func (g *irgen) delayTransform() bool {
	return g.topFuncIsGeneric
	}