src/cmd/compile/internal/types2/signature.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 types2

 import (
 	"cmd/compile/internal/syntax"
 	"fmt"
 	. "internal/types/errors"
 )

 // ----------------------------------------------------------------------------
 // API

 // A Signature represents a (non-builtin) function or method type.
 // The receiver is ignored when comparing signatures for identity.
 type Signature struct {
 	// We need to keep the scope in Signature (rather than passing it around
 	// and store it in the Func Object) because when type-checking a function
 	// literal we call the general type checker which returns a general Type.
 	// We then unpack the *Signature and use the scope for the literal body.
 	rparams  *TypeParamList // receiver type parameters from left to right, or nil
 	tparams  *TypeParamList // type parameters from left to right, or nil
 	scope    *Scope         // function scope for package-local and non-instantiated signatures; nil otherwise
 	recv     *Var           // nil if not a method
 	params   *Tuple         // (incoming) parameters from left to right; or nil
 	results  *Tuple         // (outgoing) results from left to right; or nil
 	variadic bool           // true if the last parameter's type is of the form ...T (or string, for append built-in only)
 }

 // NewSignatureType creates a new function type for the given receiver,
 // receiver type parameters, type parameters, parameters, and results. If
 // variadic is set, params must hold at least one parameter and the last
 // parameter's core type must be of unnamed slice or bytestring type.
 // If recv is non-nil, typeParams must be empty. If recvTypeParams is
 // non-empty, recv must be non-nil.
 func NewSignatureType(recv *Var, recvTypeParams, typeParams []*TypeParam, params, results *Tuple, variadic bool) *Signature {
 	if variadic {
 		n := params.Len()
 		if n == 0 {
 			panic("variadic function must have at least one parameter")
 		}
 		core := coreString(params.At(n - 1).typ)
 		if _, ok := core.(*Slice); !ok && !isString(core) {
 			panic(fmt.Sprintf("got %s, want variadic parameter with unnamed slice type or string as core type", core.String()))
 		}
 	}
 	sig := &Signature{recv: recv, params: params, results: results, variadic: variadic}
 	if len(recvTypeParams) != 0 {
 		if recv == nil {
 			panic("function with receiver type parameters must have a receiver")
 		}
 		sig.rparams = bindTParams(recvTypeParams)
 	}
 	if len(typeParams) != 0 {
 		if recv != nil {
 			panic("function with type parameters cannot have a receiver")
 		}
 		sig.tparams = bindTParams(typeParams)
 	}
 	return sig
 }

 // Recv returns the receiver of signature s (if a method), or nil if a
 // function. It is ignored when comparing signatures for identity.
 //
 // For an abstract method, Recv returns the enclosing interface either
 // as a *Named or an *Interface. Due to embedding, an interface may
 // contain methods whose receiver type is a different interface.
 func (s *Signature) Recv() *Var { return s.recv }

 // TypeParams returns the type parameters of signature s, or nil.
 func (s *Signature) TypeParams() *TypeParamList { return s.tparams }

 // SetTypeParams sets the type parameters of signature s.
 func (s *Signature) SetTypeParams(tparams []*TypeParam) { s.tparams = bindTParams(tparams) }

 // RecvTypeParams returns the receiver type parameters of signature s, or nil.
 func (s *Signature) RecvTypeParams() *TypeParamList { return s.rparams }

 // Params returns the parameters of signature s, or nil.
 func (s *Signature) Params() *Tuple { return s.params }

 // Results returns the results of signature s, or nil.
 func (s *Signature) Results() *Tuple { return s.results }

 // Variadic reports whether the signature s is variadic.
 func (s *Signature) Variadic() bool { return s.variadic }

 func (s *Signature) Underlying() Type { return s }
 func (s *Signature) String() string   { return TypeString(s, nil) }

 // ----------------------------------------------------------------------------
 // Implementation

 // funcType type-checks a function or method type.
 func (check *Checker) funcType(sig *Signature, recvPar *syntax.Field, tparams []*syntax.Field, ftyp *syntax.FuncType) {
 	check.openScope(ftyp, "function")
 	check.scope.isFunc = true
 	check.recordScope(ftyp, check.scope)
 	sig.scope = check.scope
 	defer check.closeScope()

 	if recvPar != nil {
 		// collect generic receiver type parameters, if any
 		// - a receiver type parameter is like any other type parameter, except that it is declared implicitly
 		// - the receiver specification acts as local declaration for its type parameters, which may be blank
 		_, rname, rparams := check.unpackRecv(recvPar.Type, true)
 		if len(rparams) > 0 {
 			// The scope of the type parameter T in "func (r T[T]) f()"
 			// starts after f, not at "r"; see #52038.
 			scopePos := ftyp.Pos()
 			tparams := make([]*TypeParam, len(rparams))
 			for i, rparam := range rparams {
 				tparams[i] = check.declareTypeParam(rparam, scopePos)
 			}
 			sig.rparams = bindTParams(tparams)
 			// Blank identifiers don't get declared, so naive type-checking of the
 			// receiver type expression would fail in Checker.collectParams below,
 			// when Checker.ident cannot resolve the _ to a type.
 			//
 			// Checker.recvTParamMap maps these blank identifiers to their type parameter
 			// types, so that they may be resolved in Checker.ident when they fail
 			// lookup in the scope.
 			for i, p := range rparams {
 				if p.Value == "_" {
 					if check.recvTParamMap == nil {
 						check.recvTParamMap = make(map[*syntax.Name]*TypeParam)
 					}
 					check.recvTParamMap[p] = tparams[i]
 				}
 			}
 			// determine receiver type to get its type parameters
 			// and the respective type parameter bounds
 			var recvTParams []*TypeParam
 			if rname != nil {
 				// recv should be a Named type (otherwise an error is reported elsewhere)
 				// Also: Don't report an error via genericType since it will be reported
 				//       again when we type-check the signature.
 				// TODO(gri) maybe the receiver should be marked as invalid instead?
 				if recv := asNamed(check.genericType(rname, nil)); recv != nil {
 					recvTParams = recv.TypeParams().list()
 				}
 			}
 			// provide type parameter bounds
 			if len(tparams) == len(recvTParams) {
 				smap := makeRenameMap(recvTParams, tparams)
 				for i, tpar := range tparams {
 					recvTPar := recvTParams[i]
 					check.mono.recordCanon(tpar, recvTPar)
 					// recvTPar.bound is (possibly) parameterized in the context of the
 					// receiver type declaration. Substitute parameters for the current
 					// context.
 					tpar.bound = check.subst(tpar.obj.pos, recvTPar.bound, smap, nil, check.context())
 				}
 			} else if len(tparams) < len(recvTParams) {
 				// Reporting an error here is a stop-gap measure to avoid crashes in the
 				// compiler when a type parameter/argument cannot be inferred later. It
 				// may lead to follow-on errors (see issues go.dev/issue/51339, go.dev/issue/51343).
 				// TODO(gri) find a better solution
 				got := measure(len(tparams), "type parameter")
 				check.errorf(recvPar, BadRecv, "got %s, but receiver base type declares %d", got, len(recvTParams))
 			}
 		}
 	}

 	if tparams != nil {
 		// The parser will complain about invalid type parameters for methods.
 		check.collectTypeParams(&sig.tparams, tparams)
 	}

 	// Use a temporary scope for all parameter declarations and then
 	// squash that scope into the parent scope (and report any
 	// redeclarations at that time).
 	//
 	// TODO(adonovan): now that each declaration has the correct
 	// scopePos, there should be no need for scope squashing.
 	// Audit to ensure all lookups honor scopePos and simplify.
 	scope := NewScope(check.scope, nopos, nopos, "function body (temp. scope)")
 	scopePos := syntax.EndPos(ftyp) // all parameters' scopes start after the signature
 	var recvList []*Var             // TODO(gri) remove the need for making a list here
 	if recvPar != nil {
 		recvList, _ = check.collectParams(scope, []*syntax.Field{recvPar}, false, scopePos) // use rewritten receiver type, if any
 	}
 	params, variadic := check.collectParams(scope, ftyp.ParamList, true, scopePos)
 	results, _ := check.collectParams(scope, ftyp.ResultList, false, scopePos)
 	scope.Squash(func(obj, alt Object) {
 		err := check.newError(DuplicateDecl)
 		err.addf(obj, "%s redeclared in this block", obj.Name())
 		err.addAltDecl(alt)
 		err.report()
 	})

 	if recvPar != nil {
 		// recv parameter list present (may be empty)
 		// spec: "The receiver is specified via an extra parameter section preceding the
 		// method name. That parameter section must declare a single parameter, the receiver."
 		var recv *Var
 		switch len(recvList) {
 		case 0:
 			// error reported by resolver
 			recv = NewParam(nopos, nil, "", Typ[Invalid]) // ignore recv below
 		default:
 			// more than one receiver
 			check.error(recvList[len(recvList)-1].Pos(), InvalidRecv, "method must have exactly one receiver")
 			fallthrough // continue with first receiver
 		case 1:
 			recv = recvList[0]
 		}
 		sig.recv = recv

 		// Delay validation of receiver type as it may cause premature expansion
 		// of types the receiver type is dependent on (see issues go.dev/issue/51232, go.dev/issue/51233).
 		check.later(func() {
 			// spec: "The receiver type must be of the form T or *T where T is a type name."
 			rtyp, _ := deref(recv.typ)
 			atyp := Unalias(rtyp)
 			if !isValid(atyp) {
 				return // error was reported before
 			}
 			// spec: "The type denoted by T is called the receiver base type; it must not
 			// be a pointer or interface type and it must be declared in the same package
 			// as the method."
 			switch T := atyp.(type) {
 			case *Named:
 				// The receiver type may be an instantiated type referred to
 				// by an alias (which cannot have receiver parameters for now).
 				if T.TypeArgs() != nil && sig.RecvTypeParams() == nil {
 					check.errorf(recv, InvalidRecv, "cannot define new methods on instantiated type %s", rtyp)
 					break
 				}
 				if T.obj.pkg != check.pkg {
 					check.errorf(recv, InvalidRecv, "cannot define new methods on non-local type %s", rtyp)
 					break
 				}
 				var cause string
 				switch u := T.under().(type) {
 				case *Basic:
 					// unsafe.Pointer is treated like a regular pointer
 					if u.kind == UnsafePointer {
 						cause = "unsafe.Pointer"
 					}
 				case *Pointer, *Interface:
 					cause = "pointer or interface type"
 				case *TypeParam:
 					// The underlying type of a receiver base type cannot be a
 					// type parameter: "type T[P any] P" is not a valid declaration.
 					panic("unreachable")
 				}
 				if cause != "" {
 					check.errorf(recv, InvalidRecv, "invalid receiver type %s (%s)", rtyp, cause)
 				}
 			case *Basic:
 				check.errorf(recv, InvalidRecv, "cannot define new methods on non-local type %s", rtyp)
 			default:
 				check.errorf(recv, InvalidRecv, "invalid receiver type %s", recv.typ)
 			}
 		}).describef(recv, "validate receiver %s", recv)
 	}

 	sig.params = NewTuple(params...)
 	sig.results = NewTuple(results...)
 	sig.variadic = variadic
 }

 // collectParams declares the parameters of list in scope and returns the corresponding
 // variable list.
 func (check *Checker) collectParams(scope *Scope, list []*syntax.Field, variadicOk bool, scopePos syntax.Pos) (params []*Var, variadic bool) {
 	if list == nil {
 		return
 	}

 	var named, anonymous bool

 	var typ Type
 	var prev syntax.Expr
 	for i, field := range list {
 		ftype := field.Type
 		// type-check type of grouped fields only once
 		if ftype != prev {
 			prev = ftype
 			if t, _ := ftype.(*syntax.DotsType); t != nil {
 				ftype = t.Elem
 				if variadicOk && i == len(list)-1 {
 					variadic = true
 				} else {
 					check.softErrorf(t, MisplacedDotDotDot, "can only use ... with final parameter in list")
 					// ignore ... and continue
 				}
 			}
 			typ = check.varType(ftype)
 		}
 		// The parser ensures that f.Tag is nil and we don't
 		// care if a constructed AST contains a non-nil tag.
 		if field.Name != nil {
 			// named parameter
 			name := field.Name.Value
 			if name == "" {
 				check.error(field.Name, InvalidSyntaxTree, "anonymous parameter")
 				// ok to continue
 			}
 			par := NewParam(field.Name.Pos(), check.pkg, name, typ)
 			check.declare(scope, field.Name, par, scopePos)
 			params = append(params, par)
 			named = true
 		} else {
 			// anonymous parameter
 			par := NewParam(field.Pos(), check.pkg, "", typ)
 			check.recordImplicit(field, par)
 			params = append(params, par)
 			anonymous = true
 		}
 	}

 	if named && anonymous {
 		check.error(list[0], InvalidSyntaxTree, "list contains both named and anonymous parameters")
 		// ok to continue
 	}

 	// For a variadic function, change the last parameter's type from T to []T.
 	// Since we type-checked T rather than ...T, we also need to retro-actively
 	// record the type for ...T.
 	if variadic {
 		last := params[len(params)-1]
 		last.typ = &Slice{elem: last.typ}
 		check.recordTypeAndValue(list[len(list)-1].Type, typexpr, last.typ, nil)
 	}

 	return
 }
	// 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 types2

	import (
	"cmd/compile/internal/syntax"
	"fmt"
	. "internal/types/errors"
	)

	// ----------------------------------------------------------------------------
	// API

	// A Signature represents a (non-builtin) function or method type.
	// The receiver is ignored when comparing signatures for identity.
	type Signature struct {
	// We need to keep the scope in Signature (rather than passing it around
	// and store it in the Func Object) because when type-checking a function
	// literal we call the general type checker which returns a general Type.
	// We then unpack the *Signature and use the scope for the literal body.
	rparams *TypeParamList // receiver type parameters from left to right, or nil
	tparams *TypeParamList // type parameters from left to right, or nil
	scope *Scope // function scope for package-local and non-instantiated signatures; nil otherwise
	recv *Var // nil if not a method
	params *Tuple // (incoming) parameters from left to right; or nil
	results *Tuple // (outgoing) results from left to right; or nil
	variadic bool // true if the last parameter's type is of the form ...T (or string, for append built-in only)
	}

	// NewSignatureType creates a new function type for the given receiver,
	// receiver type parameters, type parameters, parameters, and results. If
	// variadic is set, params must hold at least one parameter and the last
	// parameter's core type must be of unnamed slice or bytestring type.
	// If recv is non-nil, typeParams must be empty. If recvTypeParams is
	// non-empty, recv must be non-nil.
	func NewSignatureType(recv Var, recvTypeParams, typeParams []TypeParam, params, results Tuple, variadic bool) Signature {
	if variadic {
	n := params.Len()
	if n == 0 {
	panic("variadic function must have at least one parameter")
	}
	core := coreString(params.At(n - 1).typ)
	if _, ok := core.(*Slice); !ok && !isString(core) {
	panic(fmt.Sprintf("got %s, want variadic parameter with unnamed slice type or string as core type", core.String()))
	}
	}
	sig := &Signature{recv: recv, params: params, results: results, variadic: variadic}
	if len(recvTypeParams) != 0 {
	if recv == nil {
	panic("function with receiver type parameters must have a receiver")
	}
	sig.rparams = bindTParams(recvTypeParams)
	}
	if len(typeParams) != 0 {
	if recv != nil {
	panic("function with type parameters cannot have a receiver")
	}
	sig.tparams = bindTParams(typeParams)
	}
	return sig
	}

	// Recv returns the receiver of signature s (if a method), or nil if a
	// function. It is ignored when comparing signatures for identity.
	//
	// For an abstract method, Recv returns the enclosing interface either
	// as a Named or an Interface. Due to embedding, an interface may
	// contain methods whose receiver type is a different interface.
	func (s Signature) Recv() Var { return s.recv }

	// TypeParams returns the type parameters of signature s, or nil.
	func (s Signature) TypeParams() TypeParamList { return s.tparams }

	// SetTypeParams sets the type parameters of signature s.
	func (s Signature) SetTypeParams(tparams []TypeParam) { s.tparams = bindTParams(tparams) }

	// RecvTypeParams returns the receiver type parameters of signature s, or nil.
	func (s Signature) RecvTypeParams() TypeParamList { return s.rparams }

	// Params returns the parameters of signature s, or nil.
	func (s Signature) Params() Tuple { return s.params }

	// Results returns the results of signature s, or nil.
	func (s Signature) Results() Tuple { return s.results }

	// Variadic reports whether the signature s is variadic.
	func (s *Signature) Variadic() bool { return s.variadic }

	func (s *Signature) Underlying() Type { return s }
	func (s *Signature) String() string { return TypeString(s, nil) }

	// ----------------------------------------------------------------------------
	// Implementation

	// funcType type-checks a function or method type.
	func (check Checker) funcType(sig Signature, recvPar syntax.Field, tparams []syntax.Field, ftyp *syntax.FuncType) {
	check.openScope(ftyp, "function")
	check.scope.isFunc = true
	check.recordScope(ftyp, check.scope)
	sig.scope = check.scope
	defer check.closeScope()

	if recvPar != nil {
	// collect generic receiver type parameters, if any
	// - a receiver type parameter is like any other type parameter, except that it is declared implicitly
	// - the receiver specification acts as local declaration for its type parameters, which may be blank
	_, rname, rparams := check.unpackRecv(recvPar.Type, true)
	if len(rparams) > 0 {
	// The scope of the type parameter T in "func (r T[T]) f()"
	// starts after f, not at "r"; see #52038.
	scopePos := ftyp.Pos()
	tparams := make([]*TypeParam, len(rparams))
	for i, rparam := range rparams {
	tparams[i] = check.declareTypeParam(rparam, scopePos)
	}
	sig.rparams = bindTParams(tparams)
	// Blank identifiers don't get declared, so naive type-checking of the
	// receiver type expression would fail in Checker.collectParams below,
	// when Checker.ident cannot resolve the _ to a type.
	//
	// Checker.recvTParamMap maps these blank identifiers to their type parameter
	// types, so that they may be resolved in Checker.ident when they fail
	// lookup in the scope.
	for i, p := range rparams {
	if p.Value == "_" {
	if check.recvTParamMap == nil {
	check.recvTParamMap = make(map[syntax.Name]TypeParam)
	}
	check.recvTParamMap[p] = tparams[i]
	}
	}
	// determine receiver type to get its type parameters
	// and the respective type parameter bounds
	var recvTParams []*TypeParam
	if rname != nil {
	// recv should be a Named type (otherwise an error is reported elsewhere)
	// Also: Don't report an error via genericType since it will be reported
	// again when we type-check the signature.
	// TODO(gri) maybe the receiver should be marked as invalid instead?
	if recv := asNamed(check.genericType(rname, nil)); recv != nil {
	recvTParams = recv.TypeParams().list()
	}
	}
	// provide type parameter bounds
	if len(tparams) == len(recvTParams) {
	smap := makeRenameMap(recvTParams, tparams)
	for i, tpar := range tparams {
	recvTPar := recvTParams[i]
	check.mono.recordCanon(tpar, recvTPar)
	// recvTPar.bound is (possibly) parameterized in the context of the
	// receiver type declaration. Substitute parameters for the current
	// context.
	tpar.bound = check.subst(tpar.obj.pos, recvTPar.bound, smap, nil, check.context())
	}
	} else if len(tparams) < len(recvTParams) {
	// Reporting an error here is a stop-gap measure to avoid crashes in the
	// compiler when a type parameter/argument cannot be inferred later. It
	// may lead to follow-on errors (see issues go.dev/issue/51339, go.dev/issue/51343).
	// TODO(gri) find a better solution
	got := measure(len(tparams), "type parameter")
	check.errorf(recvPar, BadRecv, "got %s, but receiver base type declares %d", got, len(recvTParams))
	}
	}
	}

	if tparams != nil {
	// The parser will complain about invalid type parameters for methods.
	check.collectTypeParams(&sig.tparams, tparams)
	}

	// Use a temporary scope for all parameter declarations and then
	// squash that scope into the parent scope (and report any
	// redeclarations at that time).
	//
	// TODO(adonovan): now that each declaration has the correct
	// scopePos, there should be no need for scope squashing.
	// Audit to ensure all lookups honor scopePos and simplify.
	scope := NewScope(check.scope, nopos, nopos, "function body (temp. scope)")
	scopePos := syntax.EndPos(ftyp) // all parameters' scopes start after the signature
	var recvList []*Var // TODO(gri) remove the need for making a list here
	if recvPar != nil {
	recvList, _ = check.collectParams(scope, []*syntax.Field{recvPar}, false, scopePos) // use rewritten receiver type, if any
	}
	params, variadic := check.collectParams(scope, ftyp.ParamList, true, scopePos)
	results, _ := check.collectParams(scope, ftyp.ResultList, false, scopePos)
	scope.Squash(func(obj, alt Object) {
	err := check.newError(DuplicateDecl)
	err.addf(obj, "%s redeclared in this block", obj.Name())
	err.addAltDecl(alt)
	err.report()
	})

	if recvPar != nil {
	// recv parameter list present (may be empty)
	// spec: "The receiver is specified via an extra parameter section preceding the
	// method name. That parameter section must declare a single parameter, the receiver."
	var recv *Var
	switch len(recvList) {
	case 0:
	// error reported by resolver
	recv = NewParam(nopos, nil, "", Typ[Invalid]) // ignore recv below
	default:
	// more than one receiver
	check.error(recvList[len(recvList)-1].Pos(), InvalidRecv, "method must have exactly one receiver")
	fallthrough // continue with first receiver
	case 1:
	recv = recvList[0]
	}
	sig.recv = recv

	// Delay validation of receiver type as it may cause premature expansion
	// of types the receiver type is dependent on (see issues go.dev/issue/51232, go.dev/issue/51233).
	check.later(func() {
	// spec: "The receiver type must be of the form T or *T where T is a type name."
	rtyp, _ := deref(recv.typ)
	atyp := Unalias(rtyp)
	if !isValid(atyp) {
	return // error was reported before
	}
	// spec: "The type denoted by T is called the receiver base type; it must not
	// be a pointer or interface type and it must be declared in the same package
	// as the method."
	switch T := atyp.(type) {
	case *Named:
	// The receiver type may be an instantiated type referred to
	// by an alias (which cannot have receiver parameters for now).
	if T.TypeArgs() != nil && sig.RecvTypeParams() == nil {
	check.errorf(recv, InvalidRecv, "cannot define new methods on instantiated type %s", rtyp)
	break
	}
	if T.obj.pkg != check.pkg {
	check.errorf(recv, InvalidRecv, "cannot define new methods on non-local type %s", rtyp)
	break
	}
	var cause string
	switch u := T.under().(type) {
	case *Basic:
	// unsafe.Pointer is treated like a regular pointer
	if u.kind == UnsafePointer {
	cause = "unsafe.Pointer"
	}
	case Pointer, Interface:
	cause = "pointer or interface type"
	case *TypeParam:
	// The underlying type of a receiver base type cannot be a
	// type parameter: "type T[P any] P" is not a valid declaration.
	panic("unreachable")
	}
	if cause != "" {
	check.errorf(recv, InvalidRecv, "invalid receiver type %s (%s)", rtyp, cause)
	}
	case *Basic:
	check.errorf(recv, InvalidRecv, "cannot define new methods on non-local type %s", rtyp)
	default:
	check.errorf(recv, InvalidRecv, "invalid receiver type %s", recv.typ)
	}
	}).describef(recv, "validate receiver %s", recv)
	}

	sig.params = NewTuple(params...)
	sig.results = NewTuple(results...)
	sig.variadic = variadic
	}

	// collectParams declares the parameters of list in scope and returns the corresponding
	// variable list.
	func (check Checker) collectParams(scope Scope, list []syntax.Field, variadicOk bool, scopePos syntax.Pos) (params []Var, variadic bool) {
	if list == nil {
	return
	}

	var named, anonymous bool

	var typ Type
	var prev syntax.Expr
	for i, field := range list {
	ftype := field.Type
	// type-check type of grouped fields only once
	if ftype != prev {
	prev = ftype
	if t, _ := ftype.(*syntax.DotsType); t != nil {
	ftype = t.Elem
	if variadicOk && i == len(list)-1 {
	variadic = true
	} else {
	check.softErrorf(t, MisplacedDotDotDot, "can only use ... with final parameter in list")
	// ignore ... and continue
	}
	}
	typ = check.varType(ftype)
	}
	// The parser ensures that f.Tag is nil and we don't
	// care if a constructed AST contains a non-nil tag.
	if field.Name != nil {
	// named parameter
	name := field.Name.Value
	if name == "" {
	check.error(field.Name, InvalidSyntaxTree, "anonymous parameter")
	// ok to continue
	}
	par := NewParam(field.Name.Pos(), check.pkg, name, typ)
	check.declare(scope, field.Name, par, scopePos)
	params = append(params, par)
	named = true
	} else {
	// anonymous parameter
	par := NewParam(field.Pos(), check.pkg, "", typ)
	check.recordImplicit(field, par)
	params = append(params, par)
	anonymous = true
	}
	}

	if named && anonymous {
	check.error(list[0], InvalidSyntaxTree, "list contains both named and anonymous parameters")
	// ok to continue
	}

	// For a variadic function, change the last parameter's type from T to []T.
	// Since we type-checked T rather than ...T, we also need to retro-actively
	// record the type for ...T.
	if variadic {
	last := params[len(params)-1]
	last.typ = &Slice{elem: last.typ}
	check.recordTypeAndValue(list[len(list)-1].Type, typexpr, last.typ, nil)
	}

	return
	}