go decl 源码

golang decl 代码

文件路径：/src/cmd/compile/internal/types2/decl.go

// Copyright 2014 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 types2

import (
	"bytes"
	"cmd/compile/internal/syntax"
	"fmt"
	"go/constant"
)

func (err *error_) recordAltDecl(obj Object) {
	if pos := obj.Pos(); pos.IsKnown() {
		// We use "other" rather than "previous" here because
		// the first declaration seen may not be textually
		// earlier in the source.
		err.errorf(pos, "other declaration of %s", obj.Name())
	}
}

func (check *Checker) declare(scope *Scope, id *syntax.Name, obj Object, pos syntax.Pos) {
	// spec: "The blank identifier, represented by the underscore
	// character _, may be used in a declaration like any other
	// identifier but the declaration does not introduce a new
	// binding."
	if obj.Name() != "_" {
		if alt := scope.Insert(obj); alt != nil {
			var err error_
			err.errorf(obj, "%s redeclared in this block", obj.Name())
			err.recordAltDecl(alt)
			check.report(&err)
			return
		}
		obj.setScopePos(pos)
	}
	if id != nil {
		check.recordDef(id, obj)
	}
}

// pathString returns a string of the form a->b-> ... ->g for a path [a, b, ... g].
func pathString(path []Object) string {
	var s string
	for i, p := range path {
		if i > 0 {
			s += "->"
		}
		s += p.Name()
	}
	return s
}

// objDecl type-checks the declaration of obj in its respective (file) environment.
// For the meaning of def, see Checker.definedType, in typexpr.go.
func (check *Checker) objDecl(obj Object, def *Named) {
	if check.conf.Trace && obj.Type() == nil {
		if check.indent == 0 {
			fmt.Println() // empty line between top-level objects for readability
		}
		check.trace(obj.Pos(), "-- checking %s (%s, objPath = %s)", obj, obj.color(), pathString(check.objPath))
		check.indent++
		defer func() {
			check.indent--
			check.trace(obj.Pos(), "=> %s (%s)", obj, obj.color())
		}()
	}

	// Checking the declaration of obj means inferring its type
	// (and possibly its value, for constants).
	// An object's type (and thus the object) may be in one of
	// three states which are expressed by colors:
	//
	// - an object whose type is not yet known is painted white (initial color)
	// - an object whose type is in the process of being inferred is painted grey
	// - an object whose type is fully inferred is painted black
	//
	// During type inference, an object's color changes from white to grey
	// to black (pre-declared objects are painted black from the start).
	// A black object (i.e., its type) can only depend on (refer to) other black
	// ones. White and grey objects may depend on white and black objects.
	// A dependency on a grey object indicates a cycle which may or may not be
	// valid.
	//
	// When objects turn grey, they are pushed on the object path (a stack);
	// they are popped again when they turn black. Thus, if a grey object (a
	// cycle) is encountered, it is on the object path, and all the objects
	// it depends on are the remaining objects on that path. Color encoding
	// is such that the color value of a grey object indicates the index of
	// that object in the object path.

	// During type-checking, white objects may be assigned a type without
	// traversing through objDecl; e.g., when initializing constants and
	// variables. Update the colors of those objects here (rather than
	// everywhere where we set the type) to satisfy the color invariants.
	if obj.color() == white && obj.Type() != nil {
		obj.setColor(black)
		return
	}

	switch obj.color() {
	case white:
		assert(obj.Type() == nil)
		// All color values other than white and black are considered grey.
		// Because black and white are < grey, all values >= grey are grey.
		// Use those values to encode the object's index into the object path.
		obj.setColor(grey + color(check.push(obj)))
		defer func() {
			check.pop().setColor(black)
		}()

	case black:
		assert(obj.Type() != nil)
		return

	default:
		// Color values other than white or black are considered grey.
		fallthrough

	case grey:
		// We have a (possibly invalid) cycle.
		// In the existing code, this is marked by a non-nil type
		// for the object except for constants and variables whose
		// type may be non-nil (known), or nil if it depends on the
		// not-yet known initialization value.
		// In the former case, set the type to Typ[Invalid] because
		// we have an initialization cycle. The cycle error will be
		// reported later, when determining initialization order.
		// TODO(gri) Report cycle here and simplify initialization
		// order code.
		switch obj := obj.(type) {
		case *Const:
			if !check.validCycle(obj) || obj.typ == nil {
				obj.typ = Typ[Invalid]
			}

		case *Var:
			if !check.validCycle(obj) || obj.typ == nil {
				obj.typ = Typ[Invalid]
			}

		case *TypeName:
			if !check.validCycle(obj) {
				// break cycle
				// (without this, calling underlying()
				// below may lead to an endless loop
				// if we have a cycle for a defined
				// (*Named) type)
				obj.typ = Typ[Invalid]
			}

		case *Func:
			if !check.validCycle(obj) {
				// Don't set obj.typ to Typ[Invalid] here
				// because plenty of code type-asserts that
				// functions have a *Signature type. Grey
				// functions have their type set to an empty
				// signature which makes it impossible to
				// initialize a variable with the function.
			}

		default:
			unreachable()
		}
		assert(obj.Type() != nil)
		return
	}

	d := check.objMap[obj]
	if d == nil {
		check.dump("%v: %s should have been declared", obj.Pos(), obj)
		unreachable()
	}

	// save/restore current environment and set up object environment
	defer func(env environment) {
		check.environment = env
	}(check.environment)
	check.environment = environment{
		scope: d.file,
	}

	// Const and var declarations must not have initialization
	// cycles. We track them by remembering the current declaration
	// in check.decl. Initialization expressions depending on other
	// consts, vars, or functions, add dependencies to the current
	// check.decl.
	switch obj := obj.(type) {
	case *Const:
		check.decl = d // new package-level const decl
		check.constDecl(obj, d.vtyp, d.init, d.inherited)
	case *Var:
		check.decl = d // new package-level var decl
		check.varDecl(obj, d.lhs, d.vtyp, d.init)
	case *TypeName:
		// invalid recursive types are detected via path
		check.typeDecl(obj, d.tdecl, def)
		check.collectMethods(obj) // methods can only be added to top-level types
	case *Func:
		// functions may be recursive - no need to track dependencies
		check.funcDecl(obj, d)
	default:
		unreachable()
	}
}

// validCycle reports whether the cycle starting with obj is valid and
// reports an error if it is not.
func (check *Checker) validCycle(obj Object) (valid bool) {
	// The object map contains the package scope objects and the non-interface methods.
	if debug {
		info := check.objMap[obj]
		inObjMap := info != nil && (info.fdecl == nil || info.fdecl.Recv == nil) // exclude methods
		isPkgObj := obj.Parent() == check.pkg.scope
		if isPkgObj != inObjMap {
			check.dump("%v: inconsistent object map for %s (isPkgObj = %v, inObjMap = %v)", obj.Pos(), obj, isPkgObj, inObjMap)
			unreachable()
		}
	}

	// Count cycle objects.
	assert(obj.color() >= grey)
	start := obj.color() - grey // index of obj in objPath
	cycle := check.objPath[start:]
	tparCycle := false // if set, the cycle is through a type parameter list
	nval := 0          // number of (constant or variable) values in the cycle; valid if !generic
	ndef := 0          // number of type definitions in the cycle; valid if !generic
loop:
	for _, obj := range cycle {
		switch obj := obj.(type) {
		case *Const, *Var:
			nval++
		case *TypeName:
			// If we reach a generic type that is part of a cycle
			// and we are in a type parameter list, we have a cycle
			// through a type parameter list, which is invalid.
			if check.inTParamList && isGeneric(obj.typ) {
				tparCycle = true
				break loop
			}

			// Determine if the type name is an alias or not. For
			// package-level objects, use the object map which
			// provides syntactic information (which doesn't rely
			// on the order in which the objects are set up). For
			// local objects, we can rely on the order, so use
			// the object's predicate.
			// TODO(gri) It would be less fragile to always access
			// the syntactic information. We should consider storing
			// this information explicitly in the object.
			var alias bool
			if d := check.objMap[obj]; d != nil {
				alias = d.tdecl.Alias // package-level object
			} else {
				alias = obj.IsAlias() // function local object
			}
			if !alias {
				ndef++
			}
		case *Func:
			// ignored for now
		default:
			unreachable()
		}
	}

	if check.conf.Trace {
		check.trace(obj.Pos(), "## cycle detected: objPath = %s->%s (len = %d)", pathString(cycle), obj.Name(), len(cycle))
		if tparCycle {
			check.trace(obj.Pos(), "## cycle contains: generic type in a type parameter list")
		} else {
			check.trace(obj.Pos(), "## cycle contains: %d values, %d type definitions", nval, ndef)
		}
		defer func() {
			if valid {
				check.trace(obj.Pos(), "=> cycle is valid")
			} else {
				check.trace(obj.Pos(), "=> error: cycle is invalid")
			}
		}()
	}

	if !tparCycle {
		// A cycle involving only constants and variables is invalid but we
		// ignore them here because they are reported via the initialization
		// cycle check.
		if nval == len(cycle) {
			return true
		}

		// A cycle involving only types (and possibly functions) must have at least
		// one type definition to be permitted: If there is no type definition, we
		// have a sequence of alias type names which will expand ad infinitum.
		if nval == 0 && ndef > 0 {
			return true
		}
	}

	check.cycleError(cycle)
	return false
}

// cycleError reports a declaration cycle starting with
// the object in cycle that is "first" in the source.
func (check *Checker) cycleError(cycle []Object) {
	// name returns the (possibly qualified) object name.
	// This is needed because with generic types, cycles
	// may refer to imported types. See issue #50788.
	// TODO(gri) Thus functionality is used elsewhere. Factor it out.
	name := func(obj Object) string {
		var buf bytes.Buffer
		writePackage(&buf, obj.Pkg(), check.qualifier)
		buf.WriteString(obj.Name())
		return buf.String()
	}

	// TODO(gri) Should we start with the last (rather than the first) object in the cycle
	//           since that is the earliest point in the source where we start seeing the
	//           cycle? That would be more consistent with other error messages.
	i := firstInSrc(cycle)
	obj := cycle[i]
	objName := name(obj)
	// If obj is a type alias, mark it as valid (not broken) in order to avoid follow-on errors.
	tname, _ := obj.(*TypeName)
	if tname != nil && tname.IsAlias() {
		check.validAlias(tname, Typ[Invalid])
	}
	var err error_
	if tname != nil && check.conf.CompilerErrorMessages {
		err.errorf(obj, "invalid recursive type %s", objName)
	} else {
		err.errorf(obj, "illegal cycle in declaration of %s", objName)
	}
	for range cycle {
		err.errorf(obj, "%s refers to", objName)
		i++
		if i >= len(cycle) {
			i = 0
		}
		obj = cycle[i]
		objName = name(obj)
	}
	err.errorf(obj, "%s", objName)
	check.report(&err)
}

// firstInSrc reports the index of the object with the "smallest"
// source position in path. path must not be empty.
func firstInSrc(path []Object) int {
	fst, pos := 0, path[0].Pos()
	for i, t := range path[1:] {
		if t.Pos().Cmp(pos) < 0 {
			fst, pos = i+1, t.Pos()
		}
	}
	return fst
}

func (check *Checker) constDecl(obj *Const, typ, init syntax.Expr, inherited bool) {
	assert(obj.typ == nil)

	// use the correct value of iota and errpos
	defer func(iota constant.Value, errpos syntax.Pos) {
		check.iota = iota
		check.errpos = errpos
	}(check.iota, check.errpos)
	check.iota = obj.val
	check.errpos = nopos

	// provide valid constant value under all circumstances
	obj.val = constant.MakeUnknown()

	// determine type, if any
	if typ != nil {
		t := check.typ(typ)
		if !isConstType(t) {
			// don't report an error if the type is an invalid C (defined) type
			// (issue #22090)
			if under(t) != Typ[Invalid] {
				check.errorf(typ, "invalid constant type %s", t)
			}
			obj.typ = Typ[Invalid]
			return
		}
		obj.typ = t
	}

	// check initialization
	var x operand
	if init != nil {
		if inherited {
			// The initialization expression is inherited from a previous
			// constant declaration, and (error) positions refer to that
			// expression and not the current constant declaration. Use
			// the constant identifier position for any errors during
			// init expression evaluation since that is all we have
			// (see issues #42991, #42992).
			check.errpos = obj.pos
		}
		check.expr(&x, init)
	}
	check.initConst(obj, &x)
}

func (check *Checker) varDecl(obj *Var, lhs []*Var, typ, init syntax.Expr) {
	assert(obj.typ == nil)

	// If we have undefined variable types due to errors,
	// mark variables as used to avoid follow-on errors.
	// Matches compiler behavior.
	defer func() {
		if obj.typ == Typ[Invalid] {
			obj.used = true
		}
		for _, lhs := range lhs {
			if lhs.typ == Typ[Invalid] {
				lhs.used = true
			}
		}
	}()

	// determine type, if any
	if typ != nil {
		obj.typ = check.varType(typ)
		// We cannot spread the type to all lhs variables if there
		// are more than one since that would mark them as checked
		// (see Checker.objDecl) and the assignment of init exprs,
		// if any, would not be checked.
		//
		// TODO(gri) If we have no init expr, we should distribute
		// a given type otherwise we need to re-evalate the type
		// expr for each lhs variable, leading to duplicate work.
	}

	// check initialization
	if init == nil {
		if typ == nil {
			// error reported before by arityMatch
			obj.typ = Typ[Invalid]
		}
		return
	}

	if lhs == nil || len(lhs) == 1 {
		assert(lhs == nil || lhs[0] == obj)
		var x operand
		check.expr(&x, init)
		check.initVar(obj, &x, "variable declaration")
		return
	}

	if debug {
		// obj must be one of lhs
		found := false
		for _, lhs := range lhs {
			if obj == lhs {
				found = true
				break
			}
		}
		if !found {
			panic("inconsistent lhs")
		}
	}

	// We have multiple variables on the lhs and one init expr.
	// Make sure all variables have been given the same type if
	// one was specified, otherwise they assume the type of the
	// init expression values (was issue #15755).
	if typ != nil {
		for _, lhs := range lhs {
			lhs.typ = obj.typ
		}
	}

	check.initVars(lhs, []syntax.Expr{init}, nil)
}

// isImportedConstraint reports whether typ is an imported type constraint.
func (check *Checker) isImportedConstraint(typ Type) bool {
	named, _ := typ.(*Named)
	if named == nil || named.obj.pkg == check.pkg || named.obj.pkg == nil {
		return false
	}
	u, _ := named.under().(*Interface)
	return u != nil && !u.IsMethodSet()
}

func (check *Checker) typeDecl(obj *TypeName, tdecl *syntax.TypeDecl, def *Named) {
	assert(obj.typ == nil)

	var rhs Type
	check.later(func() {
		if t, _ := obj.typ.(*Named); t != nil { // type may be invalid
			check.validType(t)
		}
		// If typ is local, an error was already reported where typ is specified/defined.
		if check.isImportedConstraint(rhs) && !check.allowVersion(check.pkg, 1, 18) {
			check.versionErrorf(tdecl.Type, "go1.18", "using type constraint %s", rhs)
		}
	}).describef(obj, "validType(%s)", obj.Name())

	alias := tdecl.Alias
	if alias && tdecl.TParamList != nil {
		// The parser will ensure this but we may still get an invalid AST.
		// Complain and continue as regular type definition.
		check.error(tdecl, "generic type cannot be alias")
		alias = false
	}

	// alias declaration
	if alias {
		if !check.allowVersion(check.pkg, 1, 9) {
			check.versionErrorf(tdecl, "go1.9", "type aliases")
		}

		check.brokenAlias(obj)
		rhs = check.typ(tdecl.Type)
		check.validAlias(obj, rhs)
		return
	}

	// type definition or generic type declaration
	named := check.newNamed(obj, nil, nil)
	def.setUnderlying(named)

	if tdecl.TParamList != nil {
		check.openScope(tdecl, "type parameters")
		defer check.closeScope()
		check.collectTypeParams(&named.tparams, tdecl.TParamList)
	}

	// determine underlying type of named
	rhs = check.definedType(tdecl.Type, named)
	assert(rhs != nil)
	named.fromRHS = rhs

	// If the underlying type was not set while type-checking the right-hand
	// side, it is invalid and an error should have been reported elsewhere.
	if named.underlying == nil {
		named.underlying = Typ[Invalid]
	}

	// Disallow a lone type parameter as the RHS of a type declaration (issue #45639).
	// We don't need this restriction anymore if we make the underlying type of a type
	// parameter its constraint interface: if the RHS is a lone type parameter, we will
	// use its underlying type (like we do for any RHS in a type declaration), and its
	// underlying type is an interface and the type declaration is well defined.
	if isTypeParam(rhs) {
		check.error(tdecl.Type, "cannot use a type parameter as RHS in type declaration")
		named.underlying = Typ[Invalid]
	}
}

func (check *Checker) collectTypeParams(dst **TypeParamList, list []*syntax.Field) {
	tparams := make([]*TypeParam, len(list))

	// Declare type parameters up-front.
	// The scope of type parameters starts at the beginning of the type parameter
	// list (so we can have mutually recursive parameterized type bounds).
	for i, f := range list {
		tparams[i] = check.declareTypeParam(f.Name)
	}

	// Set the type parameters before collecting the type constraints because
	// the parameterized type may be used by the constraints (issue #47887).
	// Example: type T[P T[P]] interface{}
	*dst = bindTParams(tparams)

	// Signal to cycle detection that we are in a type parameter list.
	// We can only be inside one type parameter list at any given time:
	// function closures may appear inside a type parameter list but they
	// cannot be generic, and their bodies are processed in delayed and
	// sequential fashion. Note that with each new declaration, we save
	// the existing environment and restore it when done; thus inTParamList
	// is true exactly only when we are in a specific type parameter list.
	assert(!check.inTParamList)
	check.inTParamList = true
	defer func() {
		check.inTParamList = false
	}()

	// Keep track of bounds for later validation.
	var bound Type
	for i, f := range list {
		// Optimization: Re-use the previous type bound if it hasn't changed.
		// This also preserves the grouped output of type parameter lists
		// when printing type strings.
		if i == 0 || f.Type != list[i-1].Type {
			bound = check.bound(f.Type)
			if isTypeParam(bound) {
				// We may be able to allow this since it is now well-defined what
				// the underlying type and thus type set of a type parameter is.
				// But we may need some additional form of cycle detection within
				// type parameter lists.
				check.error(f.Type, "cannot use a type parameter as constraint")
				bound = Typ[Invalid]
			}
		}
		tparams[i].bound = bound
	}
}

func (check *Checker) bound(x syntax.Expr) Type {
	// A type set literal of the form ~T and A|B may only appear as constraint;
	// embed it in an implicit interface so that only interface type-checking
	// needs to take care of such type expressions.
	if op, _ := x.(*syntax.Operation); op != nil && (op.Op == syntax.Tilde || op.Op == syntax.Or) {
		t := check.typ(&syntax.InterfaceType{MethodList: []*syntax.Field{{Type: x}}})
		// mark t as implicit interface if all went well
		if t, _ := t.(*Interface); t != nil {
			t.implicit = true
		}
		return t
	}
	return check.typ(x)
}

func (check *Checker) declareTypeParam(name *syntax.Name) *TypeParam {
	// Use Typ[Invalid] for the type constraint to ensure that a type
	// is present even if the actual constraint has not been assigned
	// yet.
	// TODO(gri) Need to systematically review all uses of type parameter
	//           constraints to make sure we don't rely on them if they
	//           are not properly set yet.
	tname := NewTypeName(name.Pos(), check.pkg, name.Value, nil)
	tpar := check.newTypeParam(tname, Typ[Invalid])          // assigns type to tname as a side-effect
	check.declare(check.scope, name, tname, check.scope.pos) // TODO(gri) check scope position
	return tpar
}

func (check *Checker) collectMethods(obj *TypeName) {
	// get associated methods
	// (Checker.collectObjects only collects methods with non-blank names;
	// Checker.resolveBaseTypeName ensures that obj is not an alias name
	// if it has attached methods.)
	methods := check.methods[obj]
	if methods == nil {
		return
	}
	delete(check.methods, obj)
	assert(!check.objMap[obj].tdecl.Alias) // don't use TypeName.IsAlias (requires fully set up object)

	// use an objset to check for name conflicts
	var mset objset

	// spec: "If the base type is a struct type, the non-blank method
	// and field names must be distinct."
	base, _ := obj.typ.(*Named) // shouldn't fail but be conservative
	if base != nil {
		assert(base.TypeArgs().Len() == 0) // collectMethods should not be called on an instantiated type

		// See issue #52529: we must delay the expansion of underlying here, as
		// base may not be fully set-up.
		check.later(func() {
			check.checkFieldUniqueness(base)
		}).describef(obj, "verifying field uniqueness for %v", base)

		// Checker.Files may be called multiple times; additional package files
		// may add methods to already type-checked types. Add pre-existing methods
		// so that we can detect redeclarations.
		for i := 0; i < base.NumMethods(); i++ {
			m := base.Method(i)
			assert(m.name != "_")
			assert(mset.insert(m) == nil)
		}
	}

	// add valid methods
	for _, m := range methods {
		// spec: "For a base type, the non-blank names of methods bound
		// to it must be unique."
		assert(m.name != "_")
		if alt := mset.insert(m); alt != nil {
			var err error_
			if check.conf.CompilerErrorMessages {
				err.errorf(m.pos, "%s.%s redeclared in this block", obj.Name(), m.name)
			} else {
				err.errorf(m.pos, "method %s already declared for %s", m.name, obj)
			}
			err.recordAltDecl(alt)
			check.report(&err)
			continue
		}

		if base != nil {
			base.AddMethod(m)
		}
	}
}

func (check *Checker) checkFieldUniqueness(base *Named) {
	if t, _ := base.under().(*Struct); t != nil {
		var mset objset
		for i := 0; i < base.NumMethods(); i++ {
			m := base.Method(i)
			assert(m.name != "_")
			assert(mset.insert(m) == nil)
		}

		// Check that any non-blank field names of base are distinct from its
		// method names.
		for _, fld := range t.fields {
			if fld.name != "_" {
				if alt := mset.insert(fld); alt != nil {
					// Struct fields should already be unique, so we should only
					// encounter an alternate via collision with a method name.
					_ = alt.(*Func)

					// For historical consistency, we report the primary error on the
					// method, and the alt decl on the field.
					var err error_
					err.errorf(alt, "field and method with the same name %s", fld.name)
					err.recordAltDecl(fld)
					check.report(&err)
				}
			}
		}
	}
}

func (check *Checker) funcDecl(obj *Func, decl *declInfo) {
	assert(obj.typ == nil)

	// func declarations cannot use iota
	assert(check.iota == nil)

	sig := new(Signature)
	obj.typ = sig // guard against cycles

	// Avoid cycle error when referring to method while type-checking the signature.
	// This avoids a nuisance in the best case (non-parameterized receiver type) and
	// since the method is not a type, we get an error. If we have a parameterized
	// receiver type, instantiating the receiver type leads to the instantiation of
	// its methods, and we don't want a cycle error in that case.
	// TODO(gri) review if this is correct and/or whether we still need this?
	saved := obj.color_
	obj.color_ = black
	fdecl := decl.fdecl
	check.funcType(sig, fdecl.Recv, fdecl.TParamList, fdecl.Type)
	obj.color_ = saved

	if len(fdecl.TParamList) > 0 && fdecl.Body == nil {
		check.softErrorf(fdecl, "parameterized function is missing function body")
	}

	// function body must be type-checked after global declarations
	// (functions implemented elsewhere have no body)
	if !check.conf.IgnoreFuncBodies && fdecl.Body != nil {
		check.later(func() {
			check.funcBody(decl, obj.name, sig, fdecl.Body, nil)
		}).describef(obj, "func %s", obj.name)
	}
}

func (check *Checker) declStmt(list []syntax.Decl) {
	pkg := check.pkg

	first := -1                // index of first ConstDecl in the current group, or -1
	var last *syntax.ConstDecl // last ConstDecl with init expressions, or nil
	for index, decl := range list {
		if _, ok := decl.(*syntax.ConstDecl); !ok {
			first = -1 // we're not in a constant declaration
		}

		switch s := decl.(type) {
		case *syntax.ConstDecl:
			top := len(check.delayed)

			// iota is the index of the current constDecl within the group
			if first < 0 || s.Group == nil || list[index-1].(*syntax.ConstDecl).Group != s.Group {
				first = index
				last = nil
			}
			iota := constant.MakeInt64(int64(index - first))

			// determine which initialization expressions to use
			inherited := true
			switch {
			case s.Type != nil || s.Values != nil:
				last = s
				inherited = false
			case last == nil:
				last = new(syntax.ConstDecl) // make sure last exists
				inherited = false
			}

			// declare all constants
			lhs := make([]*Const, len(s.NameList))
			values := unpackExpr(last.Values)
			for i, name := range s.NameList {
				obj := NewConst(name.Pos(), pkg, name.Value, nil, iota)
				lhs[i] = obj

				var init syntax.Expr
				if i < len(values) {
					init = values[i]
				}

				check.constDecl(obj, last.Type, init, inherited)
			}

			// Constants must always have init values.
			check.arity(s.Pos(), s.NameList, values, true, inherited)

			// process function literals in init expressions before scope changes
			check.processDelayed(top)

			// spec: "The scope of a constant or variable identifier declared
			// inside a function begins at the end of the ConstSpec or VarSpec
			// (ShortVarDecl for short variable declarations) and ends at the
			// end of the innermost containing block."
			scopePos := syntax.EndPos(s)
			for i, name := range s.NameList {
				check.declare(check.scope, name, lhs[i], scopePos)
			}

		case *syntax.VarDecl:
			top := len(check.delayed)

			lhs0 := make([]*Var, len(s.NameList))
			for i, name := range s.NameList {
				lhs0[i] = NewVar(name.Pos(), pkg, name.Value, nil)
			}

			// initialize all variables
			values := unpackExpr(s.Values)
			for i, obj := range lhs0 {
				var lhs []*Var
				var init syntax.Expr
				switch len(values) {
				case len(s.NameList):
					// lhs and rhs match
					init = values[i]
				case 1:
					// rhs is expected to be a multi-valued expression
					lhs = lhs0
					init = values[0]
				default:
					if i < len(values) {
						init = values[i]
					}
				}
				check.varDecl(obj, lhs, s.Type, init)
				if len(values) == 1 {
					// If we have a single lhs variable we are done either way.
					// If we have a single rhs expression, it must be a multi-
					// valued expression, in which case handling the first lhs
					// variable will cause all lhs variables to have a type
					// assigned, and we are done as well.
					if debug {
						for _, obj := range lhs0 {
							assert(obj.typ != nil)
						}
					}
					break
				}
			}

			// If we have no type, we must have values.
			if s.Type == nil || values != nil {
				check.arity(s.Pos(), s.NameList, values, false, false)
			}

			// process function literals in init expressions before scope changes
			check.processDelayed(top)

			// declare all variables
			// (only at this point are the variable scopes (parents) set)
			scopePos := syntax.EndPos(s) // see constant declarations
			for i, name := range s.NameList {
				// see constant declarations
				check.declare(check.scope, name, lhs0[i], scopePos)
			}

		case *syntax.TypeDecl:
			obj := NewTypeName(s.Name.Pos(), pkg, s.Name.Value, nil)
			// spec: "The scope of a type identifier declared inside a function
			// begins at the identifier in the TypeSpec and ends at the end of
			// the innermost containing block."
			scopePos := s.Name.Pos()
			check.declare(check.scope, s.Name, obj, scopePos)
			// mark and unmark type before calling typeDecl; its type is still nil (see Checker.objDecl)
			obj.setColor(grey + color(check.push(obj)))
			check.typeDecl(obj, s, nil)
			check.pop().setColor(black)

		default:
			check.errorf(s, invalidAST+"unknown syntax.Decl node %T", s)
		}
	}
}

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