github.com/aloncn/graphics-go@v0.0.1/src/go/types/typexpr.go (about)

     1  // Copyright 2013 The Go Authors. All rights reserved.
     2  // Use of this source code is governed by a BSD-style
     3  // license that can be found in the LICENSE file.
     4  
     5  // This file implements type-checking of identifiers and type expressions.
     6  
     7  package types
     8  
     9  import (
    10  	"go/ast"
    11  	"go/constant"
    12  	"go/token"
    13  	"sort"
    14  	"strconv"
    15  )
    16  
    17  // ident type-checks identifier e and initializes x with the value or type of e.
    18  // If an error occurred, x.mode is set to invalid.
    19  // For the meaning of def and path, see check.typ, below.
    20  //
    21  func (check *Checker) ident(x *operand, e *ast.Ident, def *Named, path []*TypeName) {
    22  	x.mode = invalid
    23  	x.expr = e
    24  
    25  	scope, obj := check.scope.LookupParent(e.Name, check.pos)
    26  	if obj == nil {
    27  		if e.Name == "_" {
    28  			check.errorf(e.Pos(), "cannot use _ as value or type")
    29  		} else {
    30  			check.errorf(e.Pos(), "undeclared name: %s", e.Name)
    31  		}
    32  		return
    33  	}
    34  	check.recordUse(e, obj)
    35  
    36  	check.objDecl(obj, def, path)
    37  	typ := obj.Type()
    38  	assert(typ != nil)
    39  
    40  	// The object may be dot-imported: If so, remove its package from
    41  	// the map of unused dot imports for the respective file scope.
    42  	// (This code is only needed for dot-imports. Without them,
    43  	// we only have to mark variables, see *Var case below).
    44  	if pkg := obj.Pkg(); pkg != check.pkg && pkg != nil {
    45  		delete(check.unusedDotImports[scope], pkg)
    46  	}
    47  
    48  	switch obj := obj.(type) {
    49  	case *PkgName:
    50  		check.errorf(e.Pos(), "use of package %s not in selector", obj.name)
    51  		return
    52  
    53  	case *Const:
    54  		check.addDeclDep(obj)
    55  		if typ == Typ[Invalid] {
    56  			return
    57  		}
    58  		if obj == universeIota {
    59  			if check.iota == nil {
    60  				check.errorf(e.Pos(), "cannot use iota outside constant declaration")
    61  				return
    62  			}
    63  			x.val = check.iota
    64  		} else {
    65  			x.val = obj.val
    66  		}
    67  		assert(x.val != nil)
    68  		x.mode = constant_
    69  
    70  	case *TypeName:
    71  		x.mode = typexpr
    72  		// check for cycle
    73  		// (it's ok to iterate forward because each named type appears at most once in path)
    74  		for i, prev := range path {
    75  			if prev == obj {
    76  				check.errorf(obj.pos, "illegal cycle in declaration of %s", obj.name)
    77  				// print cycle
    78  				for _, obj := range path[i:] {
    79  					check.errorf(obj.Pos(), "\t%s refers to", obj.Name()) // secondary error, \t indented
    80  				}
    81  				check.errorf(obj.Pos(), "\t%s", obj.Name())
    82  				// maintain x.mode == typexpr despite error
    83  				typ = Typ[Invalid]
    84  				break
    85  			}
    86  		}
    87  
    88  	case *Var:
    89  		if obj.pkg == check.pkg {
    90  			obj.used = true
    91  		}
    92  		check.addDeclDep(obj)
    93  		if typ == Typ[Invalid] {
    94  			return
    95  		}
    96  		x.mode = variable
    97  
    98  	case *Func:
    99  		check.addDeclDep(obj)
   100  		x.mode = value
   101  
   102  	case *Builtin:
   103  		x.id = obj.id
   104  		x.mode = builtin
   105  
   106  	case *Nil:
   107  		x.mode = value
   108  
   109  	default:
   110  		unreachable()
   111  	}
   112  
   113  	x.typ = typ
   114  }
   115  
   116  // typExpr type-checks the type expression e and returns its type, or Typ[Invalid].
   117  // If def != nil, e is the type specification for the named type def, declared
   118  // in a type declaration, and def.underlying will be set to the type of e before
   119  // any components of e are type-checked. Path contains the path of named types
   120  // referring to this type.
   121  //
   122  func (check *Checker) typExpr(e ast.Expr, def *Named, path []*TypeName) (T Type) {
   123  	if trace {
   124  		check.trace(e.Pos(), "%s", e)
   125  		check.indent++
   126  		defer func() {
   127  			check.indent--
   128  			check.trace(e.Pos(), "=> %s", T)
   129  		}()
   130  	}
   131  
   132  	T = check.typExprInternal(e, def, path)
   133  	assert(isTyped(T))
   134  	check.recordTypeAndValue(e, typexpr, T, nil)
   135  
   136  	return
   137  }
   138  
   139  func (check *Checker) typ(e ast.Expr) Type {
   140  	return check.typExpr(e, nil, nil)
   141  }
   142  
   143  // funcType type-checks a function or method type.
   144  func (check *Checker) funcType(sig *Signature, recvPar *ast.FieldList, ftyp *ast.FuncType) {
   145  	scope := NewScope(check.scope, token.NoPos, token.NoPos, "function")
   146  	check.recordScope(ftyp, scope)
   147  
   148  	recvList, _ := check.collectParams(scope, recvPar, false)
   149  	params, variadic := check.collectParams(scope, ftyp.Params, true)
   150  	results, _ := check.collectParams(scope, ftyp.Results, false)
   151  
   152  	if recvPar != nil {
   153  		// recv parameter list present (may be empty)
   154  		// spec: "The receiver is specified via an extra parameter section preceding the
   155  		// method name. That parameter section must declare a single parameter, the receiver."
   156  		var recv *Var
   157  		switch len(recvList) {
   158  		case 0:
   159  			check.error(recvPar.Pos(), "method is missing receiver")
   160  			recv = NewParam(0, nil, "", Typ[Invalid]) // ignore recv below
   161  		default:
   162  			// more than one receiver
   163  			check.error(recvList[len(recvList)-1].Pos(), "method must have exactly one receiver")
   164  			fallthrough // continue with first receiver
   165  		case 1:
   166  			recv = recvList[0]
   167  		}
   168  		// spec: "The receiver type must be of the form T or *T where T is a type name."
   169  		// (ignore invalid types - error was reported before)
   170  		if t, _ := deref(recv.typ); t != Typ[Invalid] {
   171  			var err string
   172  			if T, _ := t.(*Named); T != nil {
   173  				// spec: "The type denoted by T is called the receiver base type; it must not
   174  				// be a pointer or interface type and it must be declared in the same package
   175  				// as the method."
   176  				if T.obj.pkg != check.pkg {
   177  					err = "type not defined in this package"
   178  				} else {
   179  					// TODO(gri) This is not correct if the underlying type is unknown yet.
   180  					switch u := T.underlying.(type) {
   181  					case *Basic:
   182  						// unsafe.Pointer is treated like a regular pointer
   183  						if u.kind == UnsafePointer {
   184  							err = "unsafe.Pointer"
   185  						}
   186  					case *Pointer, *Interface:
   187  						err = "pointer or interface type"
   188  					}
   189  				}
   190  			} else {
   191  				err = "basic or unnamed type"
   192  			}
   193  			if err != "" {
   194  				check.errorf(recv.pos, "invalid receiver %s (%s)", recv.typ, err)
   195  				// ok to continue
   196  			}
   197  		}
   198  		sig.recv = recv
   199  	}
   200  
   201  	sig.scope = scope
   202  	sig.params = NewTuple(params...)
   203  	sig.results = NewTuple(results...)
   204  	sig.variadic = variadic
   205  }
   206  
   207  // typExprInternal drives type checking of types.
   208  // Must only be called by typExpr.
   209  //
   210  func (check *Checker) typExprInternal(e ast.Expr, def *Named, path []*TypeName) Type {
   211  	switch e := e.(type) {
   212  	case *ast.BadExpr:
   213  		// ignore - error reported before
   214  
   215  	case *ast.Ident:
   216  		var x operand
   217  		check.ident(&x, e, def, path)
   218  
   219  		switch x.mode {
   220  		case typexpr:
   221  			typ := x.typ
   222  			def.setUnderlying(typ)
   223  			return typ
   224  		case invalid:
   225  			// ignore - error reported before
   226  		case novalue:
   227  			check.errorf(x.pos(), "%s used as type", &x)
   228  		default:
   229  			check.errorf(x.pos(), "%s is not a type", &x)
   230  		}
   231  
   232  	case *ast.SelectorExpr:
   233  		var x operand
   234  		check.selector(&x, e)
   235  
   236  		switch x.mode {
   237  		case typexpr:
   238  			typ := x.typ
   239  			def.setUnderlying(typ)
   240  			return typ
   241  		case invalid:
   242  			// ignore - error reported before
   243  		case novalue:
   244  			check.errorf(x.pos(), "%s used as type", &x)
   245  		default:
   246  			check.errorf(x.pos(), "%s is not a type", &x)
   247  		}
   248  
   249  	case *ast.ParenExpr:
   250  		return check.typExpr(e.X, def, path)
   251  
   252  	case *ast.ArrayType:
   253  		if e.Len != nil {
   254  			typ := new(Array)
   255  			def.setUnderlying(typ)
   256  			typ.len = check.arrayLength(e.Len)
   257  			typ.elem = check.typExpr(e.Elt, nil, path)
   258  			return typ
   259  
   260  		} else {
   261  			typ := new(Slice)
   262  			def.setUnderlying(typ)
   263  			typ.elem = check.typ(e.Elt)
   264  			return typ
   265  		}
   266  
   267  	case *ast.StructType:
   268  		typ := new(Struct)
   269  		def.setUnderlying(typ)
   270  		check.structType(typ, e, path)
   271  		return typ
   272  
   273  	case *ast.StarExpr:
   274  		typ := new(Pointer)
   275  		def.setUnderlying(typ)
   276  		typ.base = check.typ(e.X)
   277  		return typ
   278  
   279  	case *ast.FuncType:
   280  		typ := new(Signature)
   281  		def.setUnderlying(typ)
   282  		check.funcType(typ, nil, e)
   283  		return typ
   284  
   285  	case *ast.InterfaceType:
   286  		typ := new(Interface)
   287  		def.setUnderlying(typ)
   288  		check.interfaceType(typ, e, def, path)
   289  		return typ
   290  
   291  	case *ast.MapType:
   292  		typ := new(Map)
   293  		def.setUnderlying(typ)
   294  
   295  		typ.key = check.typ(e.Key)
   296  		typ.elem = check.typ(e.Value)
   297  
   298  		// spec: "The comparison operators == and != must be fully defined
   299  		// for operands of the key type; thus the key type must not be a
   300  		// function, map, or slice."
   301  		//
   302  		// Delay this check because it requires fully setup types;
   303  		// it is safe to continue in any case (was issue 6667).
   304  		check.delay(func() {
   305  			if !Comparable(typ.key) {
   306  				check.errorf(e.Key.Pos(), "invalid map key type %s", typ.key)
   307  			}
   308  		})
   309  
   310  		return typ
   311  
   312  	case *ast.ChanType:
   313  		typ := new(Chan)
   314  		def.setUnderlying(typ)
   315  
   316  		dir := SendRecv
   317  		switch e.Dir {
   318  		case ast.SEND | ast.RECV:
   319  			// nothing to do
   320  		case ast.SEND:
   321  			dir = SendOnly
   322  		case ast.RECV:
   323  			dir = RecvOnly
   324  		default:
   325  			check.invalidAST(e.Pos(), "unknown channel direction %d", e.Dir)
   326  			// ok to continue
   327  		}
   328  
   329  		typ.dir = dir
   330  		typ.elem = check.typ(e.Value)
   331  		return typ
   332  
   333  	default:
   334  		check.errorf(e.Pos(), "%s is not a type", e)
   335  	}
   336  
   337  	typ := Typ[Invalid]
   338  	def.setUnderlying(typ)
   339  	return typ
   340  }
   341  
   342  // typeOrNil type-checks the type expression (or nil value) e
   343  // and returns the typ of e, or nil.
   344  // If e is neither a type nor nil, typOrNil returns Typ[Invalid].
   345  //
   346  func (check *Checker) typOrNil(e ast.Expr) Type {
   347  	var x operand
   348  	check.rawExpr(&x, e, nil)
   349  	switch x.mode {
   350  	case invalid:
   351  		// ignore - error reported before
   352  	case novalue:
   353  		check.errorf(x.pos(), "%s used as type", &x)
   354  	case typexpr:
   355  		return x.typ
   356  	case value:
   357  		if x.isNil() {
   358  			return nil
   359  		}
   360  		fallthrough
   361  	default:
   362  		check.errorf(x.pos(), "%s is not a type", &x)
   363  	}
   364  	return Typ[Invalid]
   365  }
   366  
   367  func (check *Checker) arrayLength(e ast.Expr) int64 {
   368  	var x operand
   369  	check.expr(&x, e)
   370  	if x.mode != constant_ {
   371  		if x.mode != invalid {
   372  			check.errorf(x.pos(), "array length %s must be constant", &x)
   373  		}
   374  		return 0
   375  	}
   376  	if isUntyped(x.typ) || isInteger(x.typ) {
   377  		if val := constant.ToInt(x.val); val.Kind() == constant.Int {
   378  			if representableConst(val, check.conf, Typ[Int], nil) {
   379  				if n, ok := constant.Int64Val(val); ok && n >= 0 {
   380  					return n
   381  				}
   382  				check.errorf(x.pos(), "invalid array length %s", &x)
   383  				return 0
   384  			}
   385  		}
   386  	}
   387  	check.errorf(x.pos(), "array length %s must be integer", &x)
   388  	return 0
   389  }
   390  
   391  func (check *Checker) collectParams(scope *Scope, list *ast.FieldList, variadicOk bool) (params []*Var, variadic bool) {
   392  	if list == nil {
   393  		return
   394  	}
   395  
   396  	var named, anonymous bool
   397  	for i, field := range list.List {
   398  		ftype := field.Type
   399  		if t, _ := ftype.(*ast.Ellipsis); t != nil {
   400  			ftype = t.Elt
   401  			if variadicOk && i == len(list.List)-1 {
   402  				variadic = true
   403  			} else {
   404  				check.invalidAST(field.Pos(), "... not permitted")
   405  				// ignore ... and continue
   406  			}
   407  		}
   408  		typ := check.typ(ftype)
   409  		// The parser ensures that f.Tag is nil and we don't
   410  		// care if a constructed AST contains a non-nil tag.
   411  		if len(field.Names) > 0 {
   412  			// named parameter
   413  			for _, name := range field.Names {
   414  				if name.Name == "" {
   415  					check.invalidAST(name.Pos(), "anonymous parameter")
   416  					// ok to continue
   417  				}
   418  				par := NewParam(name.Pos(), check.pkg, name.Name, typ)
   419  				check.declare(scope, name, par, scope.pos)
   420  				params = append(params, par)
   421  			}
   422  			named = true
   423  		} else {
   424  			// anonymous parameter
   425  			par := NewParam(ftype.Pos(), check.pkg, "", typ)
   426  			check.recordImplicit(field, par)
   427  			params = append(params, par)
   428  			anonymous = true
   429  		}
   430  	}
   431  
   432  	if named && anonymous {
   433  		check.invalidAST(list.Pos(), "list contains both named and anonymous parameters")
   434  		// ok to continue
   435  	}
   436  
   437  	// For a variadic function, change the last parameter's type from T to []T.
   438  	if variadic && len(params) > 0 {
   439  		last := params[len(params)-1]
   440  		last.typ = &Slice{elem: last.typ}
   441  	}
   442  
   443  	return
   444  }
   445  
   446  func (check *Checker) declareInSet(oset *objset, pos token.Pos, obj Object) bool {
   447  	if alt := oset.insert(obj); alt != nil {
   448  		check.errorf(pos, "%s redeclared", obj.Name())
   449  		check.reportAltDecl(alt)
   450  		return false
   451  	}
   452  	return true
   453  }
   454  
   455  func (check *Checker) interfaceType(iface *Interface, ityp *ast.InterfaceType, def *Named, path []*TypeName) {
   456  	// empty interface: common case
   457  	if ityp.Methods == nil {
   458  		return
   459  	}
   460  
   461  	// The parser ensures that field tags are nil and we don't
   462  	// care if a constructed AST contains non-nil tags.
   463  
   464  	// use named receiver type if available (for better error messages)
   465  	var recvTyp Type = iface
   466  	if def != nil {
   467  		recvTyp = def
   468  	}
   469  
   470  	// Phase 1: Collect explicitly declared methods, the corresponding
   471  	//          signature (AST) expressions, and the list of embedded
   472  	//          type (AST) expressions. Do not resolve signatures or
   473  	//          embedded types yet to avoid cycles referring to this
   474  	//          interface.
   475  
   476  	var (
   477  		mset       objset
   478  		signatures []ast.Expr // list of corresponding method signatures
   479  		embedded   []ast.Expr // list of embedded types
   480  	)
   481  	for _, f := range ityp.Methods.List {
   482  		if len(f.Names) > 0 {
   483  			// The parser ensures that there's only one method
   484  			// and we don't care if a constructed AST has more.
   485  			name := f.Names[0]
   486  			pos := name.Pos()
   487  			// spec: "As with all method sets, in an interface type,
   488  			// each method must have a unique non-blank name."
   489  			if name.Name == "_" {
   490  				check.errorf(pos, "invalid method name _")
   491  				continue
   492  			}
   493  			// Don't type-check signature yet - use an
   494  			// empty signature now and update it later.
   495  			// Since we know the receiver, set it up now
   496  			// (required to avoid crash in ptrRecv; see
   497  			// e.g. test case for issue 6638).
   498  			// TODO(gri) Consider marking methods signatures
   499  			// as incomplete, for better error messages. See
   500  			// also the T4 and T5 tests in testdata/cycles2.src.
   501  			sig := new(Signature)
   502  			sig.recv = NewVar(pos, check.pkg, "", recvTyp)
   503  			m := NewFunc(pos, check.pkg, name.Name, sig)
   504  			if check.declareInSet(&mset, pos, m) {
   505  				iface.methods = append(iface.methods, m)
   506  				iface.allMethods = append(iface.allMethods, m)
   507  				signatures = append(signatures, f.Type)
   508  				check.recordDef(name, m)
   509  			}
   510  		} else {
   511  			// embedded type
   512  			embedded = append(embedded, f.Type)
   513  		}
   514  	}
   515  
   516  	// Phase 2: Resolve embedded interfaces. Because an interface must not
   517  	//          embed itself (directly or indirectly), each embedded interface
   518  	//          can be fully resolved without depending on any method of this
   519  	//          interface (if there is a cycle or another error, the embedded
   520  	//          type resolves to an invalid type and is ignored).
   521  	//          In particular, the list of methods for each embedded interface
   522  	//          must be complete (it cannot depend on this interface), and so
   523  	//          those methods can be added to the list of all methods of this
   524  	//          interface.
   525  
   526  	for _, e := range embedded {
   527  		pos := e.Pos()
   528  		typ := check.typExpr(e, nil, path)
   529  		// Determine underlying embedded (possibly incomplete) type
   530  		// by following its forward chain.
   531  		named, _ := typ.(*Named)
   532  		under := underlying(named)
   533  		embed, _ := under.(*Interface)
   534  		if embed == nil {
   535  			if typ != Typ[Invalid] {
   536  				check.errorf(pos, "%s is not an interface", typ)
   537  			}
   538  			continue
   539  		}
   540  		iface.embeddeds = append(iface.embeddeds, named)
   541  		// collect embedded methods
   542  		for _, m := range embed.allMethods {
   543  			if check.declareInSet(&mset, pos, m) {
   544  				iface.allMethods = append(iface.allMethods, m)
   545  			}
   546  		}
   547  	}
   548  
   549  	// Phase 3: At this point all methods have been collected for this interface.
   550  	//          It is now safe to type-check the signatures of all explicitly
   551  	//          declared methods, even if they refer to this interface via a cycle
   552  	//          and embed the methods of this interface in a parameter of interface
   553  	//          type.
   554  
   555  	for i, m := range iface.methods {
   556  		expr := signatures[i]
   557  		typ := check.typ(expr)
   558  		sig, _ := typ.(*Signature)
   559  		if sig == nil {
   560  			if typ != Typ[Invalid] {
   561  				check.invalidAST(expr.Pos(), "%s is not a method signature", typ)
   562  			}
   563  			continue // keep method with empty method signature
   564  		}
   565  		// update signature, but keep recv that was set up before
   566  		old := m.typ.(*Signature)
   567  		sig.recv = old.recv
   568  		*old = *sig // update signature (don't replace it!)
   569  	}
   570  
   571  	// TODO(gri) The list of explicit methods is only sorted for now to
   572  	// produce the same Interface as NewInterface. We may be able to
   573  	// claim source order in the future. Revisit.
   574  	sort.Sort(byUniqueMethodName(iface.methods))
   575  
   576  	// TODO(gri) The list of embedded types is only sorted for now to
   577  	// produce the same Interface as NewInterface. We may be able to
   578  	// claim source order in the future. Revisit.
   579  	sort.Sort(byUniqueTypeName(iface.embeddeds))
   580  
   581  	sort.Sort(byUniqueMethodName(iface.allMethods))
   582  }
   583  
   584  // byUniqueTypeName named type lists can be sorted by their unique type names.
   585  type byUniqueTypeName []*Named
   586  
   587  func (a byUniqueTypeName) Len() int           { return len(a) }
   588  func (a byUniqueTypeName) Less(i, j int) bool { return a[i].obj.Id() < a[j].obj.Id() }
   589  func (a byUniqueTypeName) Swap(i, j int)      { a[i], a[j] = a[j], a[i] }
   590  
   591  // byUniqueMethodName method lists can be sorted by their unique method names.
   592  type byUniqueMethodName []*Func
   593  
   594  func (a byUniqueMethodName) Len() int           { return len(a) }
   595  func (a byUniqueMethodName) Less(i, j int) bool { return a[i].Id() < a[j].Id() }
   596  func (a byUniqueMethodName) Swap(i, j int)      { a[i], a[j] = a[j], a[i] }
   597  
   598  func (check *Checker) tag(t *ast.BasicLit) string {
   599  	if t != nil {
   600  		if t.Kind == token.STRING {
   601  			if val, err := strconv.Unquote(t.Value); err == nil {
   602  				return val
   603  			}
   604  		}
   605  		check.invalidAST(t.Pos(), "incorrect tag syntax: %q", t.Value)
   606  	}
   607  	return ""
   608  }
   609  
   610  func (check *Checker) structType(styp *Struct, e *ast.StructType, path []*TypeName) {
   611  	list := e.Fields
   612  	if list == nil {
   613  		return
   614  	}
   615  
   616  	// struct fields and tags
   617  	var fields []*Var
   618  	var tags []string
   619  
   620  	// for double-declaration checks
   621  	var fset objset
   622  
   623  	// current field typ and tag
   624  	var typ Type
   625  	var tag string
   626  	// anonymous != nil indicates an anonymous field.
   627  	add := func(field *ast.Field, ident *ast.Ident, anonymous *TypeName, pos token.Pos) {
   628  		if tag != "" && tags == nil {
   629  			tags = make([]string, len(fields))
   630  		}
   631  		if tags != nil {
   632  			tags = append(tags, tag)
   633  		}
   634  
   635  		name := ident.Name
   636  		fld := NewField(pos, check.pkg, name, typ, anonymous != nil)
   637  		// spec: "Within a struct, non-blank field names must be unique."
   638  		if name == "_" || check.declareInSet(&fset, pos, fld) {
   639  			fields = append(fields, fld)
   640  			check.recordDef(ident, fld)
   641  		}
   642  		if anonymous != nil {
   643  			check.recordUse(ident, anonymous)
   644  		}
   645  	}
   646  
   647  	for _, f := range list.List {
   648  		typ = check.typExpr(f.Type, nil, path)
   649  		tag = check.tag(f.Tag)
   650  		if len(f.Names) > 0 {
   651  			// named fields
   652  			for _, name := range f.Names {
   653  				add(f, name, nil, name.Pos())
   654  			}
   655  		} else {
   656  			// anonymous field
   657  			name := anonymousFieldIdent(f.Type)
   658  			pos := f.Type.Pos()
   659  			t, isPtr := deref(typ)
   660  			switch t := t.(type) {
   661  			case *Basic:
   662  				if t == Typ[Invalid] {
   663  					// error was reported before
   664  					continue
   665  				}
   666  				// unsafe.Pointer is treated like a regular pointer
   667  				if t.kind == UnsafePointer {
   668  					check.errorf(pos, "anonymous field type cannot be unsafe.Pointer")
   669  					continue
   670  				}
   671  				add(f, name, Universe.Lookup(t.name).(*TypeName), pos)
   672  
   673  			case *Named:
   674  				// spec: "An embedded type must be specified as a type name
   675  				// T or as a pointer to a non-interface type name *T, and T
   676  				// itself may not be a pointer type."
   677  				switch u := t.underlying.(type) {
   678  				case *Basic:
   679  					// unsafe.Pointer is treated like a regular pointer
   680  					if u.kind == UnsafePointer {
   681  						check.errorf(pos, "anonymous field type cannot be unsafe.Pointer")
   682  						continue
   683  					}
   684  				case *Pointer:
   685  					check.errorf(pos, "anonymous field type cannot be a pointer")
   686  					continue
   687  				case *Interface:
   688  					if isPtr {
   689  						check.errorf(pos, "anonymous field type cannot be a pointer to an interface")
   690  						continue
   691  					}
   692  				}
   693  				add(f, name, t.obj, pos)
   694  
   695  			default:
   696  				check.invalidAST(pos, "anonymous field type %s must be named", typ)
   697  			}
   698  		}
   699  	}
   700  
   701  	styp.fields = fields
   702  	styp.tags = tags
   703  }
   704  
   705  func anonymousFieldIdent(e ast.Expr) *ast.Ident {
   706  	switch e := e.(type) {
   707  	case *ast.Ident:
   708  		return e
   709  	case *ast.StarExpr:
   710  		return anonymousFieldIdent(e.X)
   711  	case *ast.SelectorExpr:
   712  		return e.Sel
   713  	}
   714  	return nil // invalid anonymous field
   715  }