github.com/stingnevermore/go@v0.0.0-20180120041312-3810f5bfed72/src/cmd/compile/internal/gc/noder.go

github.com/stingnevermore/go@v0.0.0-20180120041312-3810f5bfed72/src/cmd/compile/internal/gc/noder.go (about)

     1  // Copyright 2016 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  package gc
     6  
     7  import (
     8  	"fmt"
     9  	"os"
    10  	"runtime"
    11  	"strconv"
    12  	"strings"
    13  	"unicode/utf8"
    14  
    15  	"cmd/compile/internal/syntax"
    16  	"cmd/compile/internal/types"
    17  	"cmd/internal/objabi"
    18  	"cmd/internal/src"
    19  )
    20  
    21  func parseFiles(filenames []string) uint {
    22  	var noders []*noder
    23  	// Limit the number of simultaneously open files.
    24  	sem := make(chan struct{}, runtime.GOMAXPROCS(0)+10)
    25  
    26  	for _, filename := range filenames {
    27  		p := &noder{err: make(chan syntax.Error)}
    28  		noders = append(noders, p)
    29  
    30  		go func(filename string) {
    31  			sem <- struct{}{}
    32  			defer func() { <-sem }()
    33  			defer close(p.err)
    34  			base := src.NewFileBase(filename, absFilename(filename))
    35  
    36  			f, err := os.Open(filename)
    37  			if err != nil {
    38  				p.error(syntax.Error{Pos: src.MakePos(base, 0, 0), Msg: err.Error()})
    39  				return
    40  			}
    41  			defer f.Close()
    42  
    43  			p.file, _ = syntax.Parse(base, f, p.error, p.pragma, fileh, syntax.CheckBranches) // errors are tracked via p.error
    44  		}(filename)
    45  	}
    46  
    47  	var lines uint
    48  	for _, p := range noders {
    49  		for e := range p.err {
    50  			yyerrorpos(e.Pos, "%s", e.Msg)
    51  		}
    52  
    53  		p.node()
    54  		lines += p.file.Lines
    55  		p.file = nil // release memory
    56  
    57  		if nsyntaxerrors != 0 {
    58  			errorexit()
    59  		}
    60  		// Always run testdclstack here, even when debug_dclstack is not set, as a sanity measure.
    61  		testdclstack()
    62  	}
    63  
    64  	return lines
    65  }
    66  
    67  func yyerrorpos(pos src.Pos, format string, args ...interface{}) {
    68  	yyerrorl(Ctxt.PosTable.XPos(pos), format, args...)
    69  }
    70  
    71  var pathPrefix string
    72  
    73  func fileh(name string) string {
    74  	return objabi.AbsFile("", name, pathPrefix)
    75  }
    76  
    77  func absFilename(name string) string {
    78  	return objabi.AbsFile(Ctxt.Pathname, name, pathPrefix)
    79  }
    80  
    81  // noder transforms package syntax's AST into a Node tree.
    82  type noder struct {
    83  	file       *syntax.File
    84  	linknames  []linkname
    85  	pragcgobuf string
    86  	err        chan syntax.Error
    87  	scope      ScopeID
    88  }
    89  
    90  func (p *noder) funchdr(n *Node) ScopeID {
    91  	old := p.scope
    92  	p.scope = 0
    93  	funchdr(n)
    94  	return old
    95  }
    96  
    97  func (p *noder) funcbody(old ScopeID) {
    98  	funcbody()
    99  	p.scope = old
   100  }
   101  
   102  func (p *noder) openScope(pos src.Pos) {
   103  	types.Markdcl()
   104  
   105  	if trackScopes {
   106  		Curfn.Func.Parents = append(Curfn.Func.Parents, p.scope)
   107  		p.scope = ScopeID(len(Curfn.Func.Parents))
   108  
   109  		p.markScope(pos)
   110  	}
   111  }
   112  
   113  func (p *noder) closeScope(pos src.Pos) {
   114  	types.Popdcl()
   115  
   116  	if trackScopes {
   117  		p.scope = Curfn.Func.Parents[p.scope-1]
   118  
   119  		p.markScope(pos)
   120  	}
   121  }
   122  
   123  func (p *noder) markScope(pos src.Pos) {
   124  	xpos := Ctxt.PosTable.XPos(pos)
   125  	if i := len(Curfn.Func.Marks); i > 0 && Curfn.Func.Marks[i-1].Pos == xpos {
   126  		Curfn.Func.Marks[i-1].Scope = p.scope
   127  	} else {
   128  		Curfn.Func.Marks = append(Curfn.Func.Marks, Mark{xpos, p.scope})
   129  	}
   130  }
   131  
   132  // closeAnotherScope is like closeScope, but it reuses the same mark
   133  // position as the last closeScope call. This is useful for "for" and
   134  // "if" statements, as their implicit blocks always end at the same
   135  // position as an explicit block.
   136  func (p *noder) closeAnotherScope() {
   137  	types.Popdcl()
   138  
   139  	if trackScopes {
   140  		p.scope = Curfn.Func.Parents[p.scope-1]
   141  		Curfn.Func.Marks[len(Curfn.Func.Marks)-1].Scope = p.scope
   142  	}
   143  }
   144  
   145  // linkname records a //go:linkname directive.
   146  type linkname struct {
   147  	pos    src.Pos
   148  	local  string
   149  	remote string
   150  }
   151  
   152  func (p *noder) node() {
   153  	types.Block = 1
   154  	imported_unsafe = false
   155  
   156  	p.lineno(p.file.PkgName)
   157  	mkpackage(p.file.PkgName.Value)
   158  
   159  	xtop = append(xtop, p.decls(p.file.DeclList)...)
   160  
   161  	for _, n := range p.linknames {
   162  		if imported_unsafe {
   163  			lookup(n.local).Linkname = n.remote
   164  		} else {
   165  			yyerrorpos(n.pos, "//go:linkname only allowed in Go files that import \"unsafe\"")
   166  		}
   167  	}
   168  
   169  	pragcgobuf += p.pragcgobuf
   170  	lineno = src.NoXPos
   171  	clearImports()
   172  }
   173  
   174  func (p *noder) decls(decls []syntax.Decl) (l []*Node) {
   175  	var cs constState
   176  
   177  	for _, decl := range decls {
   178  		p.lineno(decl)
   179  		switch decl := decl.(type) {
   180  		case *syntax.ImportDecl:
   181  			p.importDecl(decl)
   182  
   183  		case *syntax.VarDecl:
   184  			l = append(l, p.varDecl(decl)...)
   185  
   186  		case *syntax.ConstDecl:
   187  			l = append(l, p.constDecl(decl, &cs)...)
   188  
   189  		case *syntax.TypeDecl:
   190  			l = append(l, p.typeDecl(decl))
   191  
   192  		case *syntax.FuncDecl:
   193  			l = append(l, p.funcDecl(decl))
   194  
   195  		default:
   196  			panic("unhandled Decl")
   197  		}
   198  	}
   199  
   200  	return
   201  }
   202  
   203  func (p *noder) importDecl(imp *syntax.ImportDecl) {
   204  	val := p.basicLit(imp.Path)
   205  	ipkg := importfile(&val)
   206  
   207  	if ipkg == nil {
   208  		if nerrors == 0 {
   209  			Fatalf("phase error in import")
   210  		}
   211  		return
   212  	}
   213  
   214  	ipkg.Direct = true
   215  
   216  	var my *types.Sym
   217  	if imp.LocalPkgName != nil {
   218  		my = p.name(imp.LocalPkgName)
   219  	} else {
   220  		my = lookup(ipkg.Name)
   221  	}
   222  
   223  	pack := p.nod(imp, OPACK, nil, nil)
   224  	pack.Sym = my
   225  	pack.Name.Pkg = ipkg
   226  
   227  	switch my.Name {
   228  	case ".":
   229  		importdot(ipkg, pack)
   230  		return
   231  	case "init":
   232  		yyerrorl(pack.Pos, "cannot import package as init - init must be a func")
   233  		return
   234  	case "_":
   235  		return
   236  	}
   237  	if my.Def != nil {
   238  		lineno = pack.Pos
   239  		redeclare(my, "as imported package name")
   240  	}
   241  	my.Def = asTypesNode(pack)
   242  	my.Lastlineno = pack.Pos
   243  	my.Block = 1 // at top level
   244  }
   245  
   246  func (p *noder) varDecl(decl *syntax.VarDecl) []*Node {
   247  	names := p.declNames(decl.NameList)
   248  	typ := p.typeExprOrNil(decl.Type)
   249  
   250  	var exprs []*Node
   251  	if decl.Values != nil {
   252  		exprs = p.exprList(decl.Values)
   253  	}
   254  
   255  	p.lineno(decl)
   256  	return variter(names, typ, exprs)
   257  }
   258  
   259  // constState tracks state between constant specifiers within a
   260  // declaration group. This state is kept separate from noder so nested
   261  // constant declarations are handled correctly (e.g., issue 15550).
   262  type constState struct {
   263  	group  *syntax.Group
   264  	typ    *Node
   265  	values []*Node
   266  	iota   int64
   267  }
   268  
   269  func (p *noder) constDecl(decl *syntax.ConstDecl, cs *constState) []*Node {
   270  	if decl.Group == nil || decl.Group != cs.group {
   271  		*cs = constState{
   272  			group: decl.Group,
   273  		}
   274  	}
   275  
   276  	names := p.declNames(decl.NameList)
   277  	typ := p.typeExprOrNil(decl.Type)
   278  
   279  	var values []*Node
   280  	if decl.Values != nil {
   281  		values = p.exprList(decl.Values)
   282  		cs.typ, cs.values = typ, values
   283  	} else {
   284  		if typ != nil {
   285  			yyerror("const declaration cannot have type without expression")
   286  		}
   287  		typ, values = cs.typ, cs.values
   288  	}
   289  
   290  	var nn []*Node
   291  	for i, n := range names {
   292  		if i >= len(values) {
   293  			yyerror("missing value in const declaration")
   294  			break
   295  		}
   296  		v := values[i]
   297  		if decl.Values == nil {
   298  			v = treecopy(v, n.Pos)
   299  		}
   300  
   301  		n.Op = OLITERAL
   302  		declare(n, dclcontext)
   303  
   304  		n.Name.Param.Ntype = typ
   305  		n.Name.Defn = v
   306  		n.SetIota(cs.iota)
   307  
   308  		nn = append(nn, p.nod(decl, ODCLCONST, n, nil))
   309  	}
   310  
   311  	if len(values) > len(names) {
   312  		yyerror("extra expression in const declaration")
   313  	}
   314  
   315  	cs.iota++
   316  
   317  	return nn
   318  }
   319  
   320  func (p *noder) typeDecl(decl *syntax.TypeDecl) *Node {
   321  	n := p.declName(decl.Name)
   322  	n.Op = OTYPE
   323  	declare(n, dclcontext)
   324  
   325  	// decl.Type may be nil but in that case we got a syntax error during parsing
   326  	typ := p.typeExprOrNil(decl.Type)
   327  
   328  	param := n.Name.Param
   329  	param.Ntype = typ
   330  	param.Pragma = decl.Pragma
   331  	param.Alias = decl.Alias
   332  	if param.Alias && param.Pragma != 0 {
   333  		yyerror("cannot specify directive with type alias")
   334  		param.Pragma = 0
   335  	}
   336  
   337  	return p.nod(decl, ODCLTYPE, n, nil)
   338  
   339  }
   340  
   341  func (p *noder) declNames(names []*syntax.Name) []*Node {
   342  	var nodes []*Node
   343  	for _, name := range names {
   344  		nodes = append(nodes, p.declName(name))
   345  	}
   346  	return nodes
   347  }
   348  
   349  func (p *noder) declName(name *syntax.Name) *Node {
   350  	// TODO(mdempsky): Set lineno?
   351  	return dclname(p.name(name))
   352  }
   353  
   354  func (p *noder) funcDecl(fun *syntax.FuncDecl) *Node {
   355  	name := p.name(fun.Name)
   356  	t := p.signature(fun.Recv, fun.Type)
   357  	f := p.nod(fun, ODCLFUNC, nil, nil)
   358  
   359  	if fun.Recv == nil {
   360  		if name.Name == "init" {
   361  			name = renameinit()
   362  			if t.List.Len() > 0 || t.Rlist.Len() > 0 {
   363  				yyerrorl(f.Pos, "func init must have no arguments and no return values")
   364  			}
   365  		}
   366  
   367  		if localpkg.Name == "main" && name.Name == "main" {
   368  			if t.List.Len() > 0 || t.Rlist.Len() > 0 {
   369  				yyerrorl(f.Pos, "func main must have no arguments and no return values")
   370  			}
   371  		}
   372  	} else {
   373  		f.Func.Shortname = name
   374  		name = nblank.Sym // filled in by typecheckfunc
   375  	}
   376  
   377  	f.Func.Nname = newfuncname(name)
   378  	f.Func.Nname.Name.Defn = f
   379  	f.Func.Nname.Name.Param.Ntype = t
   380  
   381  	pragma := fun.Pragma
   382  	f.Func.Pragma = fun.Pragma
   383  	f.SetNoescape(pragma&Noescape != 0)
   384  	if pragma&Systemstack != 0 && pragma&Nosplit != 0 {
   385  		yyerrorl(f.Pos, "go:nosplit and go:systemstack cannot be combined")
   386  	}
   387  
   388  	if fun.Recv == nil {
   389  		declare(f.Func.Nname, PFUNC)
   390  	}
   391  
   392  	oldScope := p.funchdr(f)
   393  
   394  	if fun.Body != nil {
   395  		if f.Noescape() {
   396  			yyerrorl(f.Pos, "can only use //go:noescape with external func implementations")
   397  		}
   398  
   399  		body := p.stmts(fun.Body.List)
   400  		if body == nil {
   401  			body = []*Node{p.nod(fun, OEMPTY, nil, nil)}
   402  		}
   403  		f.Nbody.Set(body)
   404  
   405  		lineno = Ctxt.PosTable.XPos(fun.Body.Rbrace)
   406  		f.Func.Endlineno = lineno
   407  	} else {
   408  		if pure_go || strings.HasPrefix(f.funcname(), "init.") {
   409  			yyerrorl(f.Pos, "missing function body")
   410  		}
   411  	}
   412  
   413  	p.funcbody(oldScope)
   414  	return f
   415  }
   416  
   417  func (p *noder) signature(recv *syntax.Field, typ *syntax.FuncType) *Node {
   418  	n := p.nod(typ, OTFUNC, nil, nil)
   419  	if recv != nil {
   420  		n.Left = p.param(recv, false, false)
   421  	}
   422  	n.List.Set(p.params(typ.ParamList, true))
   423  	n.Rlist.Set(p.params(typ.ResultList, false))
   424  	return n
   425  }
   426  
   427  func (p *noder) params(params []*syntax.Field, dddOk bool) []*Node {
   428  	var nodes []*Node
   429  	for i, param := range params {
   430  		p.lineno(param)
   431  		nodes = append(nodes, p.param(param, dddOk, i+1 == len(params)))
   432  	}
   433  	return nodes
   434  }
   435  
   436  func (p *noder) param(param *syntax.Field, dddOk, final bool) *Node {
   437  	var name *Node
   438  	if param.Name != nil {
   439  		name = p.newname(param.Name)
   440  	}
   441  
   442  	typ := p.typeExpr(param.Type)
   443  	n := p.nod(param, ODCLFIELD, name, typ)
   444  
   445  	// rewrite ...T parameter
   446  	if typ.Op == ODDD {
   447  		if !dddOk {
   448  			yyerror("cannot use ... in receiver or result parameter list")
   449  		} else if !final {
   450  			yyerror("can only use ... with final parameter in list")
   451  		}
   452  		typ.Op = OTARRAY
   453  		typ.Right = typ.Left
   454  		typ.Left = nil
   455  		n.SetIsddd(true)
   456  		if n.Left != nil {
   457  			n.Left.SetIsddd(true)
   458  		}
   459  	}
   460  
   461  	return n
   462  }
   463  
   464  func (p *noder) exprList(expr syntax.Expr) []*Node {
   465  	if list, ok := expr.(*syntax.ListExpr); ok {
   466  		return p.exprs(list.ElemList)
   467  	}
   468  	return []*Node{p.expr(expr)}
   469  }
   470  
   471  func (p *noder) exprs(exprs []syntax.Expr) []*Node {
   472  	var nodes []*Node
   473  	for _, expr := range exprs {
   474  		nodes = append(nodes, p.expr(expr))
   475  	}
   476  	return nodes
   477  }
   478  
   479  func (p *noder) expr(expr syntax.Expr) *Node {
   480  	p.lineno(expr)
   481  	switch expr := expr.(type) {
   482  	case nil, *syntax.BadExpr:
   483  		return nil
   484  	case *syntax.Name:
   485  		return p.mkname(expr)
   486  	case *syntax.BasicLit:
   487  		return p.setlineno(expr, nodlit(p.basicLit(expr)))
   488  
   489  	case *syntax.CompositeLit:
   490  		n := p.nod(expr, OCOMPLIT, nil, nil)
   491  		if expr.Type != nil {
   492  			n.Right = p.expr(expr.Type)
   493  		}
   494  		l := p.exprs(expr.ElemList)
   495  		for i, e := range l {
   496  			l[i] = p.wrapname(expr.ElemList[i], e)
   497  		}
   498  		n.List.Set(l)
   499  		lineno = Ctxt.PosTable.XPos(expr.Rbrace)
   500  		return n
   501  	case *syntax.KeyValueExpr:
   502  		return p.nod(expr, OKEY, p.expr(expr.Key), p.wrapname(expr.Value, p.expr(expr.Value)))
   503  	case *syntax.FuncLit:
   504  		return p.funcLit(expr)
   505  	case *syntax.ParenExpr:
   506  		return p.nod(expr, OPAREN, p.expr(expr.X), nil)
   507  	case *syntax.SelectorExpr:
   508  		// parser.new_dotname
   509  		obj := p.expr(expr.X)
   510  		if obj.Op == OPACK {
   511  			obj.Name.SetUsed(true)
   512  			return oldname(restrictlookup(expr.Sel.Value, obj.Name.Pkg))
   513  		}
   514  		return p.setlineno(expr, nodSym(OXDOT, obj, p.name(expr.Sel)))
   515  	case *syntax.IndexExpr:
   516  		return p.nod(expr, OINDEX, p.expr(expr.X), p.expr(expr.Index))
   517  	case *syntax.SliceExpr:
   518  		op := OSLICE
   519  		if expr.Full {
   520  			op = OSLICE3
   521  		}
   522  		n := p.nod(expr, op, p.expr(expr.X), nil)
   523  		var index [3]*Node
   524  		for i, x := range expr.Index {
   525  			if x != nil {
   526  				index[i] = p.expr(x)
   527  			}
   528  		}
   529  		n.SetSliceBounds(index[0], index[1], index[2])
   530  		return n
   531  	case *syntax.AssertExpr:
   532  		if expr.Type == nil {
   533  			panic("unexpected AssertExpr")
   534  		}
   535  		// TODO(mdempsky): parser.pexpr uses p.expr(), but
   536  		// seems like the type field should be parsed with
   537  		// ntype? Shrug, doesn't matter here.
   538  		return p.nod(expr, ODOTTYPE, p.expr(expr.X), p.expr(expr.Type))
   539  	case *syntax.Operation:
   540  		if expr.Op == syntax.Add && expr.Y != nil {
   541  			return p.sum(expr)
   542  		}
   543  		x := p.expr(expr.X)
   544  		if expr.Y == nil {
   545  			if expr.Op == syntax.And {
   546  				x = unparen(x) // TODO(mdempsky): Needed?
   547  				if x.Op == OCOMPLIT {
   548  					// Special case for &T{...}: turn into (*T){...}.
   549  					// TODO(mdempsky): Switch back to p.nod after we
   550  					// get rid of gcCompat.
   551  					x.Right = nod(OIND, x.Right, nil)
   552  					x.Right.SetImplicit(true)
   553  					return x
   554  				}
   555  			}
   556  			return p.nod(expr, p.unOp(expr.Op), x, nil)
   557  		}
   558  		return p.nod(expr, p.binOp(expr.Op), x, p.expr(expr.Y))
   559  	case *syntax.CallExpr:
   560  		n := p.nod(expr, OCALL, p.expr(expr.Fun), nil)
   561  		n.List.Set(p.exprs(expr.ArgList))
   562  		n.SetIsddd(expr.HasDots)
   563  		return n
   564  
   565  	case *syntax.ArrayType:
   566  		var len *Node
   567  		if expr.Len != nil {
   568  			len = p.expr(expr.Len)
   569  		} else {
   570  			len = p.nod(expr, ODDD, nil, nil)
   571  		}
   572  		return p.nod(expr, OTARRAY, len, p.typeExpr(expr.Elem))
   573  	case *syntax.SliceType:
   574  		return p.nod(expr, OTARRAY, nil, p.typeExpr(expr.Elem))
   575  	case *syntax.DotsType:
   576  		return p.nod(expr, ODDD, p.typeExpr(expr.Elem), nil)
   577  	case *syntax.StructType:
   578  		return p.structType(expr)
   579  	case *syntax.InterfaceType:
   580  		return p.interfaceType(expr)
   581  	case *syntax.FuncType:
   582  		return p.signature(nil, expr)
   583  	case *syntax.MapType:
   584  		return p.nod(expr, OTMAP, p.typeExpr(expr.Key), p.typeExpr(expr.Value))
   585  	case *syntax.ChanType:
   586  		n := p.nod(expr, OTCHAN, p.typeExpr(expr.Elem), nil)
   587  		n.Etype = types.EType(p.chanDir(expr.Dir))
   588  		return n
   589  
   590  	case *syntax.TypeSwitchGuard:
   591  		n := p.nod(expr, OTYPESW, nil, p.expr(expr.X))
   592  		if expr.Lhs != nil {
   593  			n.Left = p.declName(expr.Lhs)
   594  			if isblank(n.Left) {
   595  				yyerror("invalid variable name %v in type switch", n.Left)
   596  			}
   597  		}
   598  		return n
   599  	}
   600  	panic("unhandled Expr")
   601  }
   602  
   603  // sum efficiently handles very large summation expressions (such as
   604  // in issue #16394). In particular, it avoids left recursion and
   605  // collapses string literals.
   606  func (p *noder) sum(x syntax.Expr) *Node {
   607  	// While we need to handle long sums with asymptotic
   608  	// efficiency, the vast majority of sums are very small: ~95%
   609  	// have only 2 or 3 operands, and ~99% of string literals are
   610  	// never concatenated.
   611  
   612  	adds := make([]*syntax.Operation, 0, 2)
   613  	for {
   614  		add, ok := x.(*syntax.Operation)
   615  		if !ok || add.Op != syntax.Add || add.Y == nil {
   616  			break
   617  		}
   618  		adds = append(adds, add)
   619  		x = add.X
   620  	}
   621  
   622  	// nstr is the current rightmost string literal in the
   623  	// summation (if any), and chunks holds its accumulated
   624  	// substrings.
   625  	//
   626  	// Consider the expression x + "a" + "b" + "c" + y. When we
   627  	// reach the string literal "a", we assign nstr to point to
   628  	// its corresponding Node and initialize chunks to {"a"}.
   629  	// Visiting the subsequent string literals "b" and "c", we
   630  	// simply append their values to chunks. Finally, when we
   631  	// reach the non-constant operand y, we'll join chunks to form
   632  	// "abc" and reassign the "a" string literal's value.
   633  	//
   634  	// N.B., we need to be careful about named string constants
   635  	// (indicated by Sym != nil) because 1) we can't modify their
   636  	// value, as doing so would affect other uses of the string
   637  	// constant, and 2) they may have types, which we need to
   638  	// handle correctly. For now, we avoid these problems by
   639  	// treating named string constants the same as non-constant
   640  	// operands.
   641  	var nstr *Node
   642  	chunks := make([]string, 0, 1)
   643  
   644  	n := p.expr(x)
   645  	if Isconst(n, CTSTR) && n.Sym == nil {
   646  		nstr = n
   647  		chunks = append(chunks, nstr.Val().U.(string))
   648  	}
   649  
   650  	for i := len(adds) - 1; i >= 0; i-- {
   651  		add := adds[i]
   652  
   653  		r := p.expr(add.Y)
   654  		if Isconst(r, CTSTR) && r.Sym == nil {
   655  			if nstr != nil {
   656  				// Collapse r into nstr instead of adding to n.
   657  				chunks = append(chunks, r.Val().U.(string))
   658  				continue
   659  			}
   660  
   661  			nstr = r
   662  			chunks = append(chunks, nstr.Val().U.(string))
   663  		} else {
   664  			if len(chunks) > 1 {
   665  				nstr.SetVal(Val{U: strings.Join(chunks, "")})
   666  			}
   667  			nstr = nil
   668  			chunks = chunks[:0]
   669  		}
   670  		n = p.nod(add, OADD, n, r)
   671  	}
   672  	if len(chunks) > 1 {
   673  		nstr.SetVal(Val{U: strings.Join(chunks, "")})
   674  	}
   675  
   676  	return n
   677  }
   678  
   679  func (p *noder) typeExpr(typ syntax.Expr) *Node {
   680  	// TODO(mdempsky): Be stricter? typecheck should handle errors anyway.
   681  	return p.expr(typ)
   682  }
   683  
   684  func (p *noder) typeExprOrNil(typ syntax.Expr) *Node {
   685  	if typ != nil {
   686  		return p.expr(typ)
   687  	}
   688  	return nil
   689  }
   690  
   691  func (p *noder) chanDir(dir syntax.ChanDir) types.ChanDir {
   692  	switch dir {
   693  	case 0:
   694  		return types.Cboth
   695  	case syntax.SendOnly:
   696  		return types.Csend
   697  	case syntax.RecvOnly:
   698  		return types.Crecv
   699  	}
   700  	panic("unhandled ChanDir")
   701  }
   702  
   703  func (p *noder) structType(expr *syntax.StructType) *Node {
   704  	var l []*Node
   705  	for i, field := range expr.FieldList {
   706  		p.lineno(field)
   707  		var n *Node
   708  		if field.Name == nil {
   709  			n = p.embedded(field.Type)
   710  		} else {
   711  			n = p.nod(field, ODCLFIELD, p.newname(field.Name), p.typeExpr(field.Type))
   712  		}
   713  		if i < len(expr.TagList) && expr.TagList[i] != nil {
   714  			n.SetVal(p.basicLit(expr.TagList[i]))
   715  		}
   716  		l = append(l, n)
   717  	}
   718  
   719  	p.lineno(expr)
   720  	n := p.nod(expr, OTSTRUCT, nil, nil)
   721  	n.List.Set(l)
   722  	return n
   723  }
   724  
   725  func (p *noder) interfaceType(expr *syntax.InterfaceType) *Node {
   726  	var l []*Node
   727  	for _, method := range expr.MethodList {
   728  		p.lineno(method)
   729  		var n *Node
   730  		if method.Name == nil {
   731  			n = p.nod(method, ODCLFIELD, nil, oldname(p.packname(method.Type)))
   732  		} else {
   733  			mname := p.newname(method.Name)
   734  			sig := p.typeExpr(method.Type)
   735  			sig.Left = fakeRecv()
   736  			n = p.nod(method, ODCLFIELD, mname, sig)
   737  			ifacedcl(n)
   738  		}
   739  		l = append(l, n)
   740  	}
   741  
   742  	n := p.nod(expr, OTINTER, nil, nil)
   743  	n.List.Set(l)
   744  	return n
   745  }
   746  
   747  func (p *noder) packname(expr syntax.Expr) *types.Sym {
   748  	switch expr := expr.(type) {
   749  	case *syntax.Name:
   750  		name := p.name(expr)
   751  		if n := oldname(name); n.Name != nil && n.Name.Pack != nil {
   752  			n.Name.Pack.Name.SetUsed(true)
   753  		}
   754  		return name
   755  	case *syntax.SelectorExpr:
   756  		name := p.name(expr.X.(*syntax.Name))
   757  		var pkg *types.Pkg
   758  		if asNode(name.Def) == nil || asNode(name.Def).Op != OPACK {
   759  			yyerror("%v is not a package", name)
   760  			pkg = localpkg
   761  		} else {
   762  			asNode(name.Def).Name.SetUsed(true)
   763  			pkg = asNode(name.Def).Name.Pkg
   764  		}
   765  		return restrictlookup(expr.Sel.Value, pkg)
   766  	}
   767  	panic(fmt.Sprintf("unexpected packname: %#v", expr))
   768  }
   769  
   770  func (p *noder) embedded(typ syntax.Expr) *Node {
   771  	op, isStar := typ.(*syntax.Operation)
   772  	if isStar {
   773  		if op.Op != syntax.Mul || op.Y != nil {
   774  			panic("unexpected Operation")
   775  		}
   776  		typ = op.X
   777  	}
   778  
   779  	sym := p.packname(typ)
   780  	n := nod(ODCLFIELD, newname(lookup(sym.Name)), oldname(sym))
   781  	n.SetEmbedded(true)
   782  
   783  	if isStar {
   784  		n.Right = p.nod(op, OIND, n.Right, nil)
   785  	}
   786  	return n
   787  }
   788  
   789  func (p *noder) stmts(stmts []syntax.Stmt) []*Node {
   790  	return p.stmtsFall(stmts, false)
   791  }
   792  
   793  func (p *noder) stmtsFall(stmts []syntax.Stmt, fallOK bool) []*Node {
   794  	var nodes []*Node
   795  	for i, stmt := range stmts {
   796  		s := p.stmtFall(stmt, fallOK && i+1 == len(stmts))
   797  		if s == nil {
   798  		} else if s.Op == OBLOCK && s.Ninit.Len() == 0 {
   799  			nodes = append(nodes, s.List.Slice()...)
   800  		} else {
   801  			nodes = append(nodes, s)
   802  		}
   803  	}
   804  	return nodes
   805  }
   806  
   807  func (p *noder) stmt(stmt syntax.Stmt) *Node {
   808  	return p.stmtFall(stmt, false)
   809  }
   810  
   811  func (p *noder) stmtFall(stmt syntax.Stmt, fallOK bool) *Node {
   812  	p.lineno(stmt)
   813  	switch stmt := stmt.(type) {
   814  	case *syntax.EmptyStmt:
   815  		return nil
   816  	case *syntax.LabeledStmt:
   817  		return p.labeledStmt(stmt, fallOK)
   818  	case *syntax.BlockStmt:
   819  		l := p.blockStmt(stmt)
   820  		if len(l) == 0 {
   821  			// TODO(mdempsky): Line number?
   822  			return nod(OEMPTY, nil, nil)
   823  		}
   824  		return liststmt(l)
   825  	case *syntax.ExprStmt:
   826  		return p.wrapname(stmt, p.expr(stmt.X))
   827  	case *syntax.SendStmt:
   828  		return p.nod(stmt, OSEND, p.expr(stmt.Chan), p.expr(stmt.Value))
   829  	case *syntax.DeclStmt:
   830  		return liststmt(p.decls(stmt.DeclList))
   831  	case *syntax.AssignStmt:
   832  		if stmt.Op != 0 && stmt.Op != syntax.Def {
   833  			n := p.nod(stmt, OASOP, p.expr(stmt.Lhs), p.expr(stmt.Rhs))
   834  			n.SetImplicit(stmt.Rhs == syntax.ImplicitOne)
   835  			n.Etype = types.EType(p.binOp(stmt.Op))
   836  			return n
   837  		}
   838  
   839  		n := p.nod(stmt, OAS, nil, nil) // assume common case
   840  
   841  		rhs := p.exprList(stmt.Rhs)
   842  		lhs := p.assignList(stmt.Lhs, n, stmt.Op == syntax.Def)
   843  
   844  		if len(lhs) == 1 && len(rhs) == 1 {
   845  			// common case
   846  			n.Left = lhs[0]
   847  			n.Right = rhs[0]
   848  		} else {
   849  			n.Op = OAS2
   850  			n.List.Set(lhs)
   851  			n.Rlist.Set(rhs)
   852  		}
   853  		return n
   854  
   855  	case *syntax.BranchStmt:
   856  		var op Op
   857  		switch stmt.Tok {
   858  		case syntax.Break:
   859  			op = OBREAK
   860  		case syntax.Continue:
   861  			op = OCONTINUE
   862  		case syntax.Fallthrough:
   863  			if !fallOK {
   864  				yyerror("fallthrough statement out of place")
   865  			}
   866  			op = OFALL
   867  		case syntax.Goto:
   868  			op = OGOTO
   869  		default:
   870  			panic("unhandled BranchStmt")
   871  		}
   872  		n := p.nod(stmt, op, nil, nil)
   873  		if stmt.Label != nil {
   874  			n.Left = p.newname(stmt.Label)
   875  		}
   876  		return n
   877  	case *syntax.CallStmt:
   878  		var op Op
   879  		switch stmt.Tok {
   880  		case syntax.Defer:
   881  			op = ODEFER
   882  		case syntax.Go:
   883  			op = OPROC
   884  		default:
   885  			panic("unhandled CallStmt")
   886  		}
   887  		return p.nod(stmt, op, p.expr(stmt.Call), nil)
   888  	case *syntax.ReturnStmt:
   889  		var results []*Node
   890  		if stmt.Results != nil {
   891  			results = p.exprList(stmt.Results)
   892  		}
   893  		n := p.nod(stmt, ORETURN, nil, nil)
   894  		n.List.Set(results)
   895  		if n.List.Len() == 0 && Curfn != nil {
   896  			for _, ln := range Curfn.Func.Dcl {
   897  				if ln.Class() == PPARAM {
   898  					continue
   899  				}
   900  				if ln.Class() != PPARAMOUT {
   901  					break
   902  				}
   903  				if asNode(ln.Sym.Def) != ln {
   904  					yyerror("%s is shadowed during return", ln.Sym.Name)
   905  				}
   906  			}
   907  		}
   908  		return n
   909  	case *syntax.IfStmt:
   910  		return p.ifStmt(stmt)
   911  	case *syntax.ForStmt:
   912  		return p.forStmt(stmt)
   913  	case *syntax.SwitchStmt:
   914  		return p.switchStmt(stmt)
   915  	case *syntax.SelectStmt:
   916  		return p.selectStmt(stmt)
   917  	}
   918  	panic("unhandled Stmt")
   919  }
   920  
   921  func (p *noder) assignList(expr syntax.Expr, defn *Node, colas bool) []*Node {
   922  	if !colas {
   923  		return p.exprList(expr)
   924  	}
   925  
   926  	defn.SetColas(true)
   927  
   928  	var exprs []syntax.Expr
   929  	if list, ok := expr.(*syntax.ListExpr); ok {
   930  		exprs = list.ElemList
   931  	} else {
   932  		exprs = []syntax.Expr{expr}
   933  	}
   934  
   935  	res := make([]*Node, len(exprs))
   936  	seen := make(map[*types.Sym]bool, len(exprs))
   937  
   938  	newOrErr := false
   939  	for i, expr := range exprs {
   940  		p.lineno(expr)
   941  		res[i] = nblank
   942  
   943  		name, ok := expr.(*syntax.Name)
   944  		if !ok {
   945  			yyerrorpos(expr.Pos(), "non-name %v on left side of :=", p.expr(expr))
   946  			newOrErr = true
   947  			continue
   948  		}
   949  
   950  		sym := p.name(name)
   951  		if sym.IsBlank() {
   952  			continue
   953  		}
   954  
   955  		if seen[sym] {
   956  			yyerrorpos(expr.Pos(), "%v repeated on left side of :=", sym)
   957  			newOrErr = true
   958  			continue
   959  		}
   960  		seen[sym] = true
   961  
   962  		if sym.Block == types.Block {
   963  			res[i] = oldname(sym)
   964  			continue
   965  		}
   966  
   967  		newOrErr = true
   968  		n := newname(sym)
   969  		declare(n, dclcontext)
   970  		n.Name.Defn = defn
   971  		defn.Ninit.Append(nod(ODCL, n, nil))
   972  		res[i] = n
   973  	}
   974  
   975  	if !newOrErr {
   976  		yyerrorl(defn.Pos, "no new variables on left side of :=")
   977  	}
   978  	return res
   979  }
   980  
   981  func (p *noder) blockStmt(stmt *syntax.BlockStmt) []*Node {
   982  	p.openScope(stmt.Pos())
   983  	nodes := p.stmts(stmt.List)
   984  	p.closeScope(stmt.Rbrace)
   985  	return nodes
   986  }
   987  
   988  func (p *noder) ifStmt(stmt *syntax.IfStmt) *Node {
   989  	p.openScope(stmt.Pos())
   990  	n := p.nod(stmt, OIF, nil, nil)
   991  	if stmt.Init != nil {
   992  		n.Ninit.Set1(p.stmt(stmt.Init))
   993  	}
   994  	if stmt.Cond != nil {
   995  		n.Left = p.expr(stmt.Cond)
   996  	}
   997  	n.Nbody.Set(p.blockStmt(stmt.Then))
   998  	if stmt.Else != nil {
   999  		e := p.stmt(stmt.Else)
  1000  		if e.Op == OBLOCK && e.Ninit.Len() == 0 {
  1001  			n.Rlist.Set(e.List.Slice())
  1002  		} else {
  1003  			n.Rlist.Set1(e)
  1004  		}
  1005  	}
  1006  	p.closeAnotherScope()
  1007  	return n
  1008  }
  1009  
  1010  func (p *noder) forStmt(stmt *syntax.ForStmt) *Node {
  1011  	p.openScope(stmt.Pos())
  1012  	var n *Node
  1013  	if r, ok := stmt.Init.(*syntax.RangeClause); ok {
  1014  		if stmt.Cond != nil || stmt.Post != nil {
  1015  			panic("unexpected RangeClause")
  1016  		}
  1017  
  1018  		n = p.nod(r, ORANGE, nil, p.expr(r.X))
  1019  		if r.Lhs != nil {
  1020  			n.List.Set(p.assignList(r.Lhs, n, r.Def))
  1021  		}
  1022  	} else {
  1023  		n = p.nod(stmt, OFOR, nil, nil)
  1024  		if stmt.Init != nil {
  1025  			n.Ninit.Set1(p.stmt(stmt.Init))
  1026  		}
  1027  		if stmt.Cond != nil {
  1028  			n.Left = p.expr(stmt.Cond)
  1029  		}
  1030  		if stmt.Post != nil {
  1031  			n.Right = p.stmt(stmt.Post)
  1032  		}
  1033  	}
  1034  	n.Nbody.Set(p.blockStmt(stmt.Body))
  1035  	p.closeAnotherScope()
  1036  	return n
  1037  }
  1038  
  1039  func (p *noder) switchStmt(stmt *syntax.SwitchStmt) *Node {
  1040  	p.openScope(stmt.Pos())
  1041  	n := p.nod(stmt, OSWITCH, nil, nil)
  1042  	if stmt.Init != nil {
  1043  		n.Ninit.Set1(p.stmt(stmt.Init))
  1044  	}
  1045  	if stmt.Tag != nil {
  1046  		n.Left = p.expr(stmt.Tag)
  1047  	}
  1048  
  1049  	tswitch := n.Left
  1050  	if tswitch != nil && tswitch.Op != OTYPESW {
  1051  		tswitch = nil
  1052  	}
  1053  	n.List.Set(p.caseClauses(stmt.Body, tswitch, stmt.Rbrace))
  1054  
  1055  	p.closeScope(stmt.Rbrace)
  1056  	return n
  1057  }
  1058  
  1059  func (p *noder) caseClauses(clauses []*syntax.CaseClause, tswitch *Node, rbrace src.Pos) []*Node {
  1060  	var nodes []*Node
  1061  	for i, clause := range clauses {
  1062  		p.lineno(clause)
  1063  		if i > 0 {
  1064  			p.closeScope(clause.Pos())
  1065  		}
  1066  		p.openScope(clause.Pos())
  1067  
  1068  		n := p.nod(clause, OXCASE, nil, nil)
  1069  		if clause.Cases != nil {
  1070  			n.List.Set(p.exprList(clause.Cases))
  1071  		}
  1072  		if tswitch != nil && tswitch.Left != nil {
  1073  			nn := newname(tswitch.Left.Sym)
  1074  			declare(nn, dclcontext)
  1075  			n.Rlist.Set1(nn)
  1076  			// keep track of the instances for reporting unused
  1077  			nn.Name.Defn = tswitch
  1078  		}
  1079  
  1080  		// Trim trailing empty statements. We omit them from
  1081  		// the Node AST anyway, and it's easier to identify
  1082  		// out-of-place fallthrough statements without them.
  1083  		body := clause.Body
  1084  		for len(body) > 0 {
  1085  			if _, ok := body[len(body)-1].(*syntax.EmptyStmt); !ok {
  1086  				break
  1087  			}
  1088  			body = body[:len(body)-1]
  1089  		}
  1090  
  1091  		n.Nbody.Set(p.stmtsFall(body, true))
  1092  		if l := n.Nbody.Len(); l > 0 && n.Nbody.Index(l-1).Op == OFALL {
  1093  			if tswitch != nil {
  1094  				yyerror("cannot fallthrough in type switch")
  1095  			}
  1096  			if i+1 == len(clauses) {
  1097  				yyerror("cannot fallthrough final case in switch")
  1098  			}
  1099  		}
  1100  
  1101  		nodes = append(nodes, n)
  1102  	}
  1103  	if len(clauses) > 0 {
  1104  		p.closeScope(rbrace)
  1105  	}
  1106  	return nodes
  1107  }
  1108  
  1109  func (p *noder) selectStmt(stmt *syntax.SelectStmt) *Node {
  1110  	n := p.nod(stmt, OSELECT, nil, nil)
  1111  	n.List.Set(p.commClauses(stmt.Body, stmt.Rbrace))
  1112  	return n
  1113  }
  1114  
  1115  func (p *noder) commClauses(clauses []*syntax.CommClause, rbrace src.Pos) []*Node {
  1116  	var nodes []*Node
  1117  	for i, clause := range clauses {
  1118  		p.lineno(clause)
  1119  		if i > 0 {
  1120  			p.closeScope(clause.Pos())
  1121  		}
  1122  		p.openScope(clause.Pos())
  1123  
  1124  		n := p.nod(clause, OXCASE, nil, nil)
  1125  		if clause.Comm != nil {
  1126  			n.List.Set1(p.stmt(clause.Comm))
  1127  		}
  1128  		n.Nbody.Set(p.stmts(clause.Body))
  1129  		nodes = append(nodes, n)
  1130  	}
  1131  	if len(clauses) > 0 {
  1132  		p.closeScope(rbrace)
  1133  	}
  1134  	return nodes
  1135  }
  1136  
  1137  func (p *noder) labeledStmt(label *syntax.LabeledStmt, fallOK bool) *Node {
  1138  	lhs := p.nod(label, OLABEL, p.newname(label.Label), nil)
  1139  
  1140  	var ls *Node
  1141  	if label.Stmt != nil { // TODO(mdempsky): Should always be present.
  1142  		ls = p.stmtFall(label.Stmt, fallOK)
  1143  	}
  1144  
  1145  	lhs.Name.Defn = ls
  1146  	l := []*Node{lhs}
  1147  	if ls != nil {
  1148  		if ls.Op == OBLOCK && ls.Ninit.Len() == 0 {
  1149  			l = append(l, ls.List.Slice()...)
  1150  		} else {
  1151  			l = append(l, ls)
  1152  		}
  1153  	}
  1154  	return liststmt(l)
  1155  }
  1156  
  1157  var unOps = [...]Op{
  1158  	syntax.Recv: ORECV,
  1159  	syntax.Mul:  OIND,
  1160  	syntax.And:  OADDR,
  1161  
  1162  	syntax.Not: ONOT,
  1163  	syntax.Xor: OCOM,
  1164  	syntax.Add: OPLUS,
  1165  	syntax.Sub: OMINUS,
  1166  }
  1167  
  1168  func (p *noder) unOp(op syntax.Operator) Op {
  1169  	if uint64(op) >= uint64(len(unOps)) || unOps[op] == 0 {
  1170  		panic("invalid Operator")
  1171  	}
  1172  	return unOps[op]
  1173  }
  1174  
  1175  var binOps = [...]Op{
  1176  	syntax.OrOr:   OOROR,
  1177  	syntax.AndAnd: OANDAND,
  1178  
  1179  	syntax.Eql: OEQ,
  1180  	syntax.Neq: ONE,
  1181  	syntax.Lss: OLT,
  1182  	syntax.Leq: OLE,
  1183  	syntax.Gtr: OGT,
  1184  	syntax.Geq: OGE,
  1185  
  1186  	syntax.Add: OADD,
  1187  	syntax.Sub: OSUB,
  1188  	syntax.Or:  OOR,
  1189  	syntax.Xor: OXOR,
  1190  
  1191  	syntax.Mul:    OMUL,
  1192  	syntax.Div:    ODIV,
  1193  	syntax.Rem:    OMOD,
  1194  	syntax.And:    OAND,
  1195  	syntax.AndNot: OANDNOT,
  1196  	syntax.Shl:    OLSH,
  1197  	syntax.Shr:    ORSH,
  1198  }
  1199  
  1200  func (p *noder) binOp(op syntax.Operator) Op {
  1201  	if uint64(op) >= uint64(len(binOps)) || binOps[op] == 0 {
  1202  		panic("invalid Operator")
  1203  	}
  1204  	return binOps[op]
  1205  }
  1206  
  1207  func (p *noder) basicLit(lit *syntax.BasicLit) Val {
  1208  	// TODO: Don't try to convert if we had syntax errors (conversions may fail).
  1209  	//       Use dummy values so we can continue to compile. Eventually, use a
  1210  	//       form of "unknown" literals that are ignored during type-checking so
  1211  	//       we can continue type-checking w/o spurious follow-up errors.
  1212  	switch s := lit.Value; lit.Kind {
  1213  	case syntax.IntLit:
  1214  		x := new(Mpint)
  1215  		x.SetString(s)
  1216  		return Val{U: x}
  1217  
  1218  	case syntax.FloatLit:
  1219  		x := newMpflt()
  1220  		x.SetString(s)
  1221  		return Val{U: x}
  1222  
  1223  	case syntax.ImagLit:
  1224  		x := new(Mpcplx)
  1225  		x.Imag.SetString(strings.TrimSuffix(s, "i"))
  1226  		return Val{U: x}
  1227  
  1228  	case syntax.RuneLit:
  1229  		var r rune
  1230  		if u, err := strconv.Unquote(s); err == nil && len(u) > 0 {
  1231  			// Package syntax already reported any errors.
  1232  			// Check for them again though because 0 is a
  1233  			// better fallback value for invalid rune
  1234  			// literals than 0xFFFD.
  1235  			if len(u) == 1 {
  1236  				r = rune(u[0])
  1237  			} else {
  1238  				r, _ = utf8.DecodeRuneInString(u)
  1239  			}
  1240  		}
  1241  		x := new(Mpint)
  1242  		x.SetInt64(int64(r))
  1243  		x.Rune = true
  1244  		return Val{U: x}
  1245  
  1246  	case syntax.StringLit:
  1247  		if len(s) > 0 && s[0] == '`' {
  1248  			// strip carriage returns from raw string
  1249  			s = strings.Replace(s, "\r", "", -1)
  1250  		}
  1251  		// Ignore errors because package syntax already reported them.
  1252  		u, _ := strconv.Unquote(s)
  1253  		return Val{U: u}
  1254  
  1255  	default:
  1256  		panic("unhandled BasicLit kind")
  1257  	}
  1258  }
  1259  
  1260  func (p *noder) name(name *syntax.Name) *types.Sym {
  1261  	return lookup(name.Value)
  1262  }
  1263  
  1264  func (p *noder) mkname(name *syntax.Name) *Node {
  1265  	// TODO(mdempsky): Set line number?
  1266  	return mkname(p.name(name))
  1267  }
  1268  
  1269  func (p *noder) newname(name *syntax.Name) *Node {
  1270  	// TODO(mdempsky): Set line number?
  1271  	return newname(p.name(name))
  1272  }
  1273  
  1274  func (p *noder) wrapname(n syntax.Node, x *Node) *Node {
  1275  	// These nodes do not carry line numbers.
  1276  	// Introduce a wrapper node to give them the correct line.
  1277  	switch x.Op {
  1278  	case OTYPE, OLITERAL:
  1279  		if x.Sym == nil {
  1280  			break
  1281  		}
  1282  		fallthrough
  1283  	case ONAME, ONONAME, OPACK:
  1284  		x = p.nod(n, OPAREN, x, nil)
  1285  		x.SetImplicit(true)
  1286  	}
  1287  	return x
  1288  }
  1289  
  1290  func (p *noder) nod(orig syntax.Node, op Op, left, right *Node) *Node {
  1291  	return p.setlineno(orig, nod(op, left, right))
  1292  }
  1293  
  1294  func (p *noder) setlineno(src_ syntax.Node, dst *Node) *Node {
  1295  	pos := src_.Pos()
  1296  	if !pos.IsKnown() {
  1297  		// TODO(mdempsky): Shouldn't happen. Fix package syntax.
  1298  		return dst
  1299  	}
  1300  	dst.Pos = Ctxt.PosTable.XPos(pos)
  1301  	return dst
  1302  }
  1303  
  1304  func (p *noder) lineno(n syntax.Node) {
  1305  	if n == nil {
  1306  		return
  1307  	}
  1308  	pos := n.Pos()
  1309  	if !pos.IsKnown() {
  1310  		// TODO(mdempsky): Shouldn't happen. Fix package syntax.
  1311  		return
  1312  	}
  1313  	lineno = Ctxt.PosTable.XPos(pos)
  1314  }
  1315  
  1316  // error is called concurrently if files are parsed concurrently.
  1317  func (p *noder) error(err error) {
  1318  	p.err <- err.(syntax.Error)
  1319  }
  1320  
  1321  // pragmas that are allowed in the std lib, but don't have
  1322  // a syntax.Pragma value (see lex.go) associated with them.
  1323  var allowedStdPragmas = map[string]bool{
  1324  	"go:cgo_export_static":  true,
  1325  	"go:cgo_export_dynamic": true,
  1326  	"go:cgo_import_static":  true,
  1327  	"go:cgo_import_dynamic": true,
  1328  	"go:cgo_ldflag":         true,
  1329  	"go:cgo_dynamic_linker": true,
  1330  	"go:generate":           true,
  1331  }
  1332  
  1333  // pragma is called concurrently if files are parsed concurrently.
  1334  func (p *noder) pragma(pos src.Pos, text string) syntax.Pragma {
  1335  	switch {
  1336  	case strings.HasPrefix(text, "line "):
  1337  		// line directives are handled by syntax package
  1338  		panic("unreachable")
  1339  
  1340  	case strings.HasPrefix(text, "go:linkname "):
  1341  		f := strings.Fields(text)
  1342  		if len(f) != 3 {
  1343  			p.error(syntax.Error{Pos: pos, Msg: "usage: //go:linkname localname linkname"})
  1344  			break
  1345  		}
  1346  		p.linknames = append(p.linknames, linkname{pos, f[1], f[2]})
  1347  
  1348  	case strings.HasPrefix(text, "go:cgo_"):
  1349  		p.pragcgobuf += p.pragcgo(pos, text)
  1350  		fallthrough // because of //go:cgo_unsafe_args
  1351  	default:
  1352  		verb := text
  1353  		if i := strings.Index(text, " "); i >= 0 {
  1354  			verb = verb[:i]
  1355  		}
  1356  		prag := pragmaValue(verb)
  1357  		const runtimePragmas = Systemstack | Nowritebarrier | Nowritebarrierrec | Yeswritebarrierrec
  1358  		if !compiling_runtime && prag&runtimePragmas != 0 {
  1359  			p.error(syntax.Error{Pos: pos, Msg: fmt.Sprintf("//%s only allowed in runtime", verb)})
  1360  		}
  1361  		if prag == 0 && !allowedStdPragmas[verb] && compiling_std {
  1362  			p.error(syntax.Error{Pos: pos, Msg: fmt.Sprintf("//%s is not allowed in the standard library", verb)})
  1363  		}
  1364  		return prag
  1365  	}
  1366  
  1367  	return 0
  1368  }
  1369  
  1370  func mkname(sym *types.Sym) *Node {
  1371  	n := oldname(sym)
  1372  	if n.Name != nil && n.Name.Pack != nil {
  1373  		n.Name.Pack.Name.SetUsed(true)
  1374  	}
  1375  	return n
  1376  }
  1377  
  1378  func unparen(x *Node) *Node {
  1379  	for x.Op == OPAREN {
  1380  		x = x.Left
  1381  	}
  1382  	return x
  1383  }