Esempio n. 1
0
func (p *exporter) value(x exact.Value) {
	if trace {
		p.tracef("value { ")
		defer p.tracef("} ")
	}

	switch kind := x.Kind(); kind {
	case exact.Bool:
		tag := falseTag
		if exact.BoolVal(x) {
			tag = trueTag
		}
		p.int(tag)
	case exact.Int:
		if i, ok := exact.Int64Val(x); ok {
			p.int(int64Tag)
			p.int64(i)
			return
		}
		p.int(floatTag)
		p.float(x)
	case exact.Float:
		p.int(fractionTag)
		p.fraction(x)
	case exact.Complex:
		p.int(complexTag)
		p.fraction(exact.Real(x))
		p.fraction(exact.Imag(x))
	case exact.String:
		p.int(stringTag)
		p.string(exact.StringVal(x))
	default:
		panic(fmt.Sprintf("unexpected value kind %d", kind))
	}
}
Esempio n. 2
0
File: print.go Progetto: 4honor/obdi
// checkPrintf checks a call to a formatted print routine such as Printf.
// call.Args[formatIndex] is (well, should be) the format argument.
func (f *File) checkPrintf(call *ast.CallExpr, name string, formatIndex int) {
	if formatIndex >= len(call.Args) {
		f.Bad(call.Pos(), "too few arguments in call to", name)
		return
	}
	lit := f.pkg.types[call.Args[formatIndex]].Value
	if lit == nil {
		if *verbose {
			f.Warn(call.Pos(), "can't check non-constant format in call to", name)
		}
		return
	}
	if lit.Kind() != exact.String {
		f.Badf(call.Pos(), "constant %v not a string in call to %s", lit, name)
		return
	}
	format := exact.StringVal(lit)
	firstArg := formatIndex + 1 // Arguments are immediately after format string.
	if !strings.Contains(format, "%") {
		if len(call.Args) > firstArg {
			f.Badf(call.Pos(), "no formatting directive in %s call", name)
		}
		return
	}
	// Hard part: check formats against args.
	argNum := firstArg
	indexed := false
	for i, w := 0, 0; i < len(format); i += w {
		w = 1
		if format[i] == '%' {
			state := f.parsePrintfVerb(call, name, format[i:], firstArg, argNum)
			if state == nil {
				return
			}
			w = len(state.format)
			if state.indexed {
				indexed = true
			}
			if !f.okPrintfArg(call, state) { // One error per format is enough.
				return
			}
			if len(state.argNums) > 0 {
				// Continue with the next sequential argument.
				argNum = state.argNums[len(state.argNums)-1] + 1
			}
		}
	}
	// Dotdotdot is hard.
	if call.Ellipsis.IsValid() && argNum >= len(call.Args)-1 {
		return
	}
	// If the arguments were direct indexed, we assume the programmer knows what's up.
	// Otherwise, there should be no leftover arguments.
	if !indexed && argNum != len(call.Args) {
		expect := argNum - firstArg
		numArgs := len(call.Args) - firstArg
		f.Badf(call.Pos(), "wrong number of args for format in %s call: %d needed but %d args", name, expect, numArgs)
	}
}
Esempio n. 3
0
//ranges through config file and checks all expressions.
// prints result messages to stdout
func (c *checker) CheckAll() ([]CheckResult, error) {
	result := []CheckResult{}
	cnf, err := conf.ReadConfigFile(c.configFile)
	if err != nil {
		return nil, err
	}
	for _, section := range cnf.GetSections() {
		if section == "default" {
			continue
		}
		expr, _ := cnf.GetString(section, "expr")
		_, r, err := types.Eval(expr, c.pkg, c.sc)
		if err != nil {
			fmt.Fprintln(os.Stderr, err)
			continue
		}
		cr := &CheckResult{
			Name: section,
		}
		var m string
		if exact.BoolVal(r) {
			m, err = cnf.GetString(section, "true")
			if err != nil {
				continue
			}
		} else {
			m, err = cnf.GetString(section, "false")
			if err != nil {
				continue
			}
		}
		val, err := cnf.GetString(section, "val")
		if err == nil {
			t, v, err := types.Eval(val, c.pkg, c.sc)
			if err == nil {
				if types.Identical(t, types.Typ[types.UntypedFloat]) || types.Identical(t, types.Typ[types.Float64]) {
					x, _ := exact.Float64Val(v)
					cr.Value = x
				}
			}
		}
		owner, err := cnf.GetString(section, "owner")
		if err == nil {
			cr.Owner = owner
		} else {
			cr.Owner = "unknown"
		}

		_, msg, err := types.Eval(m, c.pkg, c.sc)
		if err != nil {
			cr.Message = m
		} else {
			cr.Message = exact.StringVal(msg)
		}
		result = append(result, *cr)
	}
	return result, nil
}
Esempio n. 4
0
File: ops.go Progetto: 4honor/obdi
// constValue returns the value of the constant with the
// dynamic type tag appropriate for c.Type().
func constValue(c *ssa.Const) value {
	if c.IsNil() {
		return zero(c.Type()) // typed nil
	}

	if t, ok := c.Type().Underlying().(*types.Basic); ok {
		// TODO(adonovan): eliminate untyped constants from SSA form.
		switch t.Kind() {
		case types.Bool, types.UntypedBool:
			return exact.BoolVal(c.Value)
		case types.Int, types.UntypedInt:
			// Assume sizeof(int) is same on host and target.
			return int(c.Int64())
		case types.Int8:
			return int8(c.Int64())
		case types.Int16:
			return int16(c.Int64())
		case types.Int32, types.UntypedRune:
			return int32(c.Int64())
		case types.Int64:
			return c.Int64()
		case types.Uint:
			// Assume sizeof(uint) is same on host and target.
			return uint(c.Uint64())
		case types.Uint8:
			return uint8(c.Uint64())
		case types.Uint16:
			return uint16(c.Uint64())
		case types.Uint32:
			return uint32(c.Uint64())
		case types.Uint64:
			return c.Uint64()
		case types.Uintptr:
			// Assume sizeof(uintptr) is same on host and target.
			return uintptr(c.Uint64())
		case types.Float32:
			return float32(c.Float64())
		case types.Float64, types.UntypedFloat:
			return c.Float64()
		case types.Complex64:
			return complex64(c.Complex128())
		case types.Complex128, types.UntypedComplex:
			return c.Complex128()
		case types.String, types.UntypedString:
			if c.Value.Kind() == exact.String {
				return exact.StringVal(c.Value)
			}
			return string(rune(c.Int64()))
		}
	}

	panic(fmt.Sprintf("constValue: %s", c))
}
Esempio n. 5
0
func (c *Const) Name() string {
	var s string
	if c.Value.Kind() == exact.String {
		s = exact.StringVal(c.Value)
		const max = 20
		if len(s) > max {
			s = s[:max-3] + "..." // abbreviate
		}
		s = strconv.Quote(s)
	} else {
		s = c.Value.String()
	}
	return s + ":" + c.typ.String()
}
Esempio n. 6
0
func (l *Literal) Name() string {
	var s string
	if l.Value.Kind() == exact.String {
		s = exact.StringVal(l.Value)
		const maxLit = 20
		if len(s) > maxLit {
			s = s[:maxLit-3] + "..." // abbreviate
		}
		s = strconv.Quote(s)
	} else {
		s = l.Value.String()
	}
	return s + ":" + l.Type_.String()
}
Esempio n. 7
0
func (c *Const) valstring() string {
	if c.Value == nil {
		return "nil"
	} else if c.Value.Kind() == exact.String {
		s := exact.StringVal(c.Value)
		const max = 20
		if len(s) > max {
			s = s[:max-3] + "..." // abbreviate
		}
		return strconv.Quote(s)
	} else {
		return c.Value.String()
	}
}
Esempio n. 8
0
func (c *funcContext) identifierConstant(expr ast.Expr) (string, bool) {
	val := c.p.info.Types[expr].Value
	if val == nil {
		return "", false
	}
	s := exact.StringVal(val)
	if len(s) == 0 {
		return "", false
	}
	for i, c := range s {
		if !((c >= 'a' && c <= 'z') || (c >= 'A' && c <= 'Z') || (i > 0 && c >= '0' && c <= '9') || c == '_' || c == '$') {
			return "", false
		}
	}
	return s, true
}
Esempio n. 9
0
File: const.go Progetto: 4honor/obdi
func (c *Const) RelString(from *types.Package) string {
	var s string
	if c.Value == nil {
		s = "nil"
	} else if c.Value.Kind() == exact.String {
		s = exact.StringVal(c.Value)
		const max = 20
		// TODO(adonovan): don't cut a rune in half.
		if len(s) > max {
			s = s[:max-3] + "..." // abbreviate
		}
		s = strconv.Quote(s)
	} else {
		s = c.Value.String()
	}
	return s + ":" + relType(c.Type(), from)
}
Esempio n. 10
0
func ext۰reflect۰rtype۰MethodByName(a *analysis, cgn *cgnode) {
	// If we have access to the callsite,
	// and the argument is a string constant,
	// return only that method.
	var name string
	if site := cgn.callersite; site != nil {
		if c, ok := site.instr.Common().Args[0].(*ssa.Const); ok {
			name = exact.StringVal(c.Value)
		}
	}

	a.addConstraint(&rtypeMethodByNameConstraint{
		cgn:    cgn,
		name:   name,
		t:      a.funcParams(cgn.obj),
		result: a.funcResults(cgn.obj),
	})
}
Esempio n. 11
0
func analyzeNapParam(pkg *types.Package, info *types.Info, c *ast.CallExpr) (string, bool) {
	sel, ok := c.Fun.(*ast.SelectorExpr)
	if !ok {
		return "", false
	}

	xType := info.Types[sel.X]
	if xType.Type == nil {
		return "", false
	}

	if xType.Type.String() != "github.com/Logiraptor/nap.Request" {
		return "", false
	}
	// printNode(c)

	nameTV := info.Types[c.Args[0]]

	return exact.StringVal(nameTV.Value), true
}
Esempio n. 12
0
func Test(t *testing.T) {
	switch runtime.GOOS {
	case "windows":
		t.Skipf("skipping test on %q (no /usr/bin/diff)", runtime.GOOS)
	}

	conf := loader.Config{
		Fset:          token.NewFileSet(),
		ParserMode:    parser.ParseComments,
		SourceImports: true,
	}

	// Each entry is a single-file package.
	// (Multi-file packages aren't interesting for this test.)
	// Order matters: each non-template package is processed using
	// the preceding template package.
	for _, filename := range []string{
		"testdata/A.template",
		"testdata/A1.go",
		"testdata/A2.go",

		"testdata/B.template",
		"testdata/B1.go",

		"testdata/C.template",
		"testdata/C1.go",

		"testdata/D.template",
		"testdata/D1.go",

		"testdata/E.template",
		"testdata/E1.go",

		"testdata/bad_type.template",
		"testdata/no_before.template",
		"testdata/no_after_return.template",
		"testdata/type_mismatch.template",
		"testdata/expr_type_mismatch.template",
	} {
		pkgname := strings.TrimSuffix(filepath.Base(filename), ".go")
		if err := conf.CreateFromFilenames(pkgname, filename); err != nil {
			t.Fatal(err)
		}
	}
	iprog, err := conf.Load()
	if err != nil {
		t.Fatal(err)
	}

	var xform *eg.Transformer
	for _, info := range iprog.Created {
		file := info.Files[0]
		filename := iprog.Fset.File(file.Pos()).Name() // foo.go

		if strings.HasSuffix(filename, "template") {
			// a new template
			shouldFail, _ := info.Pkg.Scope().Lookup("shouldFail").(*types.Const)
			xform, err = eg.NewTransformer(iprog.Fset, info, *verboseFlag)
			if err != nil {
				if shouldFail == nil {
					t.Errorf("NewTransformer(%s): %s", filename, err)
				} else if want := exact.StringVal(shouldFail.Val()); !strings.Contains(err.Error(), want) {
					t.Errorf("NewTransformer(%s): got error %q, want error %q", filename, err, want)
				}
			} else if shouldFail != nil {
				t.Errorf("NewTransformer(%s) succeeded unexpectedly; want error %q",
					filename, shouldFail.Val())
			}
			continue
		}

		if xform == nil {
			t.Errorf("%s: no previous template", filename)
			continue
		}

		// apply previous template to this package
		n := xform.Transform(&info.Info, info.Pkg, file)
		if n == 0 {
			t.Errorf("%s: no matches", filename)
			continue
		}

		got := filename + "t"       // foo.got
		golden := filename + "lden" // foo.golden

		// Write actual output to foo.got.
		if err := eg.WriteAST(iprog.Fset, got, file); err != nil {
			t.Error(err)
		}
		defer os.Remove(got)

		// Compare foo.got with foo.golden.
		var cmd *exec.Cmd
		switch runtime.GOOS {
		case "plan9":
			cmd = exec.Command("/bin/diff", "-c", golden, got)
		default:
			cmd = exec.Command("/usr/bin/diff", "-u", golden, got)
		}
		buf := new(bytes.Buffer)
		cmd.Stdout = buf
		cmd.Stderr = os.Stderr
		if err := cmd.Run(); err != nil {
			t.Errorf("eg tests for %s failed: %s.\n%s\n", filename, err, buf)

			if *updateFlag {
				t.Logf("Updating %s...", golden)
				if err := exec.Command("/bin/cp", got, golden).Run(); err != nil {
					t.Errorf("Update failed: %s", err)
				}
			}
		}
	}
}
Esempio n. 13
0
func (c *PkgContext) translateExpr(expr ast.Expr) string {
	exprType := c.info.Types[expr]
	if value, valueFound := c.info.Values[expr]; valueFound {
		basic := types.Typ[types.String]
		if value.Kind() != exact.String { // workaround for bug in go/types
			basic = exprType.Underlying().(*types.Basic)
		}
		switch {
		case basic.Info()&types.IsBoolean != 0:
			return strconv.FormatBool(exact.BoolVal(value))
		case basic.Info()&types.IsInteger != 0:
			if is64Bit(basic) {
				d, _ := exact.Uint64Val(value)
				return fmt.Sprintf("new %s(%d, %d)", c.typeName(exprType), d>>32, d&(1<<32-1))
			}
			d, _ := exact.Int64Val(value)
			return strconv.FormatInt(d, 10)
		case basic.Info()&types.IsFloat != 0:
			f, _ := exact.Float64Val(value)
			return strconv.FormatFloat(f, 'g', -1, 64)
		case basic.Info()&types.IsComplex != 0:
			r, _ := exact.Float64Val(exact.Real(value))
			i, _ := exact.Float64Val(exact.Imag(value))
			if basic.Kind() == types.UntypedComplex {
				exprType = types.Typ[types.Complex128]
			}
			return fmt.Sprintf("new %s(%s, %s)", c.typeName(exprType), strconv.FormatFloat(r, 'g', -1, 64), strconv.FormatFloat(i, 'g', -1, 64))
		case basic.Info()&types.IsString != 0:
			buffer := bytes.NewBuffer(nil)
			for _, r := range []byte(exact.StringVal(value)) {
				switch r {
				case '\b':
					buffer.WriteString(`\b`)
				case '\f':
					buffer.WriteString(`\f`)
				case '\n':
					buffer.WriteString(`\n`)
				case '\r':
					buffer.WriteString(`\r`)
				case '\t':
					buffer.WriteString(`\t`)
				case '\v':
					buffer.WriteString(`\v`)
				case '"':
					buffer.WriteString(`\"`)
				case '\\':
					buffer.WriteString(`\\`)
				default:
					if r < 0x20 || r > 0x7E {
						fmt.Fprintf(buffer, `\x%02X`, r)
						continue
					}
					buffer.WriteByte(r)
				}
			}
			return `"` + buffer.String() + `"`
		default:
			panic("Unhandled constant type: " + basic.String())
		}
	}

	switch e := expr.(type) {
	case *ast.CompositeLit:
		if ptrType, isPointer := exprType.(*types.Pointer); isPointer {
			exprType = ptrType.Elem()
		}

		collectIndexedElements := func(elementType types.Type) []string {
			elements := make([]string, 0)
			i := 0
			zero := c.zeroValue(elementType)
			for _, element := range e.Elts {
				if kve, isKve := element.(*ast.KeyValueExpr); isKve {
					key, _ := exact.Int64Val(c.info.Values[kve.Key])
					i = int(key)
					element = kve.Value
				}
				for len(elements) <= i {
					elements = append(elements, zero)
				}
				elements[i] = c.translateExprToType(element, elementType)
				i++
			}
			return elements
		}

		switch t := exprType.Underlying().(type) {
		case *types.Array:
			elements := collectIndexedElements(t.Elem())
			if len(elements) != 0 {
				zero := c.zeroValue(t.Elem())
				for len(elements) < int(t.Len()) {
					elements = append(elements, zero)
				}
				return createListComposite(t.Elem(), elements)
			}
			return fmt.Sprintf("Go$makeArray(%s, %d, function() { return %s; })", toArrayType(t.Elem()), t.Len(), c.zeroValue(t.Elem()))
		case *types.Slice:
			return fmt.Sprintf("new %s(%s)", c.typeName(exprType), createListComposite(t.Elem(), collectIndexedElements(t.Elem())))
		case *types.Map:
			elements := make([]string, len(e.Elts)*2)
			for i, element := range e.Elts {
				kve := element.(*ast.KeyValueExpr)
				elements[i*2] = c.translateExprToType(kve.Key, t.Key())
				elements[i*2+1] = c.translateExprToType(kve.Value, t.Elem())
			}
			return fmt.Sprintf("new %s([%s])", c.typeName(exprType), strings.Join(elements, ", "))
		case *types.Struct:
			elements := make([]string, t.NumFields())
			isKeyValue := true
			if len(e.Elts) != 0 {
				_, isKeyValue = e.Elts[0].(*ast.KeyValueExpr)
			}
			if !isKeyValue {
				for i, element := range e.Elts {
					elements[i] = c.translateExprToType(element, t.Field(i).Type())
				}
			}
			if isKeyValue {
				for i := range elements {
					elements[i] = c.zeroValue(t.Field(i).Type())
				}
				for _, element := range e.Elts {
					kve := element.(*ast.KeyValueExpr)
					for j := range elements {
						if kve.Key.(*ast.Ident).Name == t.Field(j).Name() {
							elements[j] = c.translateExprToType(kve.Value, t.Field(j).Type())
							break
						}
					}
				}
			}
			if named, isNamed := exprType.(*types.Named); isNamed {
				return fmt.Sprintf("new %s(%s)", c.objectName(named.Obj()), strings.Join(elements, ", "))
			}
			structVar := c.newVariable("_struct")
			c.translateTypeSpec(&ast.TypeSpec{
				Name: c.newIdent(structVar, t),
				Type: e.Type,
			})
			return fmt.Sprintf("new %s(%s)", structVar, strings.Join(elements, ", "))
		default:
			panic(fmt.Sprintf("Unhandled CompositeLit type: %T\n", t))
		}

	case *ast.FuncLit:
		return strings.TrimSpace(string(c.CatchOutput(func() {
			c.newScope(func() {
				params := c.translateParams(e.Type)
				closurePrefix := "("
				closureSuffix := ")"
				if len(c.escapingVars) != 0 {
					list := strings.Join(c.escapingVars, ", ")
					closurePrefix = "(function(" + list + ") { return "
					closureSuffix = "; })(" + list + ")"
				}
				c.Printf("%sfunction(%s) {", closurePrefix, strings.Join(params, ", "))
				c.Indent(func() {
					c.translateFunctionBody(e.Body.List, exprType.(*types.Signature))
				})
				c.Printf("}%s", closureSuffix)
			})
		})))

	case *ast.UnaryExpr:
		switch e.Op {
		case token.AND:
			switch c.info.Types[e.X].Underlying().(type) {
			case *types.Struct, *types.Array:
				return c.translateExpr(e.X)
			default:
				if _, isComposite := e.X.(*ast.CompositeLit); isComposite {
					return fmt.Sprintf("Go$newDataPointer(%s, %s)", c.translateExpr(e.X), c.typeName(c.info.Types[e]))
				}
				closurePrefix := ""
				closureSuffix := ""
				if len(c.escapingVars) != 0 {
					list := strings.Join(c.escapingVars, ", ")
					closurePrefix = "(function(" + list + ") { return "
					closureSuffix = "; })(" + list + ")"
				}
				vVar := c.newVariable("v")
				return fmt.Sprintf("%snew %s(function() { return %s; }, function(%s) { %s; })%s", closurePrefix, c.typeName(exprType), c.translateExpr(e.X), vVar, c.translateAssign(e.X, vVar), closureSuffix)
			}
		case token.ARROW:
			return "undefined"
		}

		t := c.info.Types[e.X]
		basic := t.Underlying().(*types.Basic)
		op := e.Op.String()
		switch e.Op {
		case token.ADD:
			return c.translateExpr(e.X)
		case token.SUB:
			if is64Bit(basic) {
				x := c.newVariable("x")
				return fmt.Sprintf("(%s = %s, new %s(-%s.high, -%s.low))", x, c.translateExpr(e.X), c.typeName(t), x, x)
			}
			if basic.Info()&types.IsComplex != 0 {
				x := c.newVariable("x")
				return fmt.Sprintf("(%s = %s, new %s(-%s.real, -%s.imag))", x, c.translateExpr(e.X), c.typeName(t), x, x)
			}
		case token.XOR:
			if is64Bit(basic) {
				x := c.newVariable("x")
				return fmt.Sprintf("(%s = %s, new %s(~%s.high, ~%s.low >>> 0))", x, c.translateExpr(e.X), c.typeName(t), x, x)
			}
			op = "~"
		}
		return fixNumber(fmt.Sprintf("%s%s", op, c.translateExpr(e.X)), basic)

	case *ast.BinaryExpr:
		if e.Op == token.NEQ {
			return fmt.Sprintf("!(%s)", c.translateExpr(&ast.BinaryExpr{
				X:  e.X,
				Op: token.EQL,
				Y:  e.Y,
			}))
		}

		t := c.info.Types[e.X]
		t2 := c.info.Types[e.Y]
		_, isInterface := t2.Underlying().(*types.Interface)
		if isInterface {
			t = t2
		}

		if basic, isBasic := t.Underlying().(*types.Basic); isBasic && basic.Info()&types.IsNumeric != 0 {
			if is64Bit(basic) {
				var expr string
				switch e.Op {
				case token.MUL:
					return fmt.Sprintf("Go$mul64(%s, %s)", c.translateExpr(e.X), c.translateExpr(e.Y))
				case token.QUO:
					return fmt.Sprintf("Go$div64(%s, %s, false)", c.translateExpr(e.X), c.translateExpr(e.Y))
				case token.REM:
					return fmt.Sprintf("Go$div64(%s, %s, true)", c.translateExpr(e.X), c.translateExpr(e.Y))
				case token.SHL:
					return fmt.Sprintf("Go$shiftLeft64(%s, %s)", c.translateExpr(e.X), c.flatten64(e.Y))
				case token.SHR:
					return fmt.Sprintf("Go$shiftRight%s(%s, %s)", toJavaScriptType(basic), c.translateExpr(e.X), c.flatten64(e.Y))
				case token.EQL:
					expr = "x.high === y.high && x.low === y.low"
				case token.LSS:
					expr = "x.high < y.high || (x.high === y.high && x.low < y.low)"
				case token.LEQ:
					expr = "x.high < y.high || (x.high === y.high && x.low <= y.low)"
				case token.GTR:
					expr = "x.high > y.high || (x.high === y.high && x.low > y.low)"
				case token.GEQ:
					expr = "x.high > y.high || (x.high === y.high && x.low >= y.low)"
				case token.ADD, token.SUB:
					expr = fmt.Sprintf("new %s(x.high %s y.high, x.low %s y.low)", c.typeName(t), e.Op, e.Op)
				case token.AND, token.OR, token.XOR:
					expr = fmt.Sprintf("new %s(x.high %s y.high, (x.low %s y.low) >>> 0)", c.typeName(t), e.Op, e.Op)
				case token.AND_NOT:
					expr = fmt.Sprintf("new %s(x.high &~ y.high, (x.low &~ y.low) >>> 0)", c.typeName(t))
				default:
					panic(e.Op)
				}
				x := c.newVariable("x")
				y := c.newVariable("y")
				expr = strings.Replace(expr, "x.", x+".", -1)
				expr = strings.Replace(expr, "y.", y+".", -1)
				return fmt.Sprintf("(%s = %s, %s = %s, %s)", x, c.translateExpr(e.X), y, c.translateExpr(e.Y), expr)
			}

			if basic.Info()&types.IsComplex != 0 {
				var expr string
				switch e.Op {
				case token.EQL:
					expr = "x.real === y.real && x.imag === y.imag"
				case token.ADD, token.SUB:
					expr = fmt.Sprintf("new %s(x.real %s y.real, x.imag %s y.imag)", c.typeName(t), e.Op, e.Op)
				case token.MUL:
					expr = fmt.Sprintf("new %s(x.real * y.real - x.imag * y.imag, x.real * y.imag + x.imag * y.real)", c.typeName(t))
				case token.QUO:
					return fmt.Sprintf("Go$divComplex(%s, %s)", c.translateExpr(e.X), c.translateExpr(e.Y))
				default:
					panic(e.Op)
				}
				x := c.newVariable("x")
				y := c.newVariable("y")
				expr = strings.Replace(expr, "x.", x+".", -1)
				expr = strings.Replace(expr, "y.", y+".", -1)
				return fmt.Sprintf("(%s = %s, %s = %s, %s)", x, c.translateExpr(e.X), y, c.translateExpr(e.Y), expr)
			}

			switch e.Op {
			case token.EQL:
				return fmt.Sprintf("%s === %s", c.translateExpr(e.X), c.translateExpr(e.Y))
			case token.LSS, token.LEQ, token.GTR, token.GEQ:
				return fmt.Sprintf("%s %s %s", c.translateExpr(e.X), e.Op, c.translateExpr(e.Y))
			case token.ADD, token.SUB:
				return fixNumber(fmt.Sprintf("%s %s %s", c.translateExpr(e.X), e.Op, c.translateExpr(e.Y)), basic)
			case token.MUL:
				if basic.Kind() == types.Int32 {
					x := c.newVariable("x")
					y := c.newVariable("y")
					return fmt.Sprintf("(%s = %s, %s = %s, (((%s >>> 16 << 16) * %s >> 0) + (%s << 16 >>> 16) * %s) >> 0)", x, c.translateExpr(e.X), y, c.translateExpr(e.Y), x, y, x, y)
				}
				if basic.Kind() == types.Uint32 || basic.Kind() == types.Uintptr {
					x := c.newVariable("x")
					y := c.newVariable("y")
					return fmt.Sprintf("(%s = %s, %s = %s, (((%s >>> 16 << 16) * %s >>> 0) + (%s << 16 >>> 16) * %s) >>> 0)", x, c.translateExpr(e.X), y, c.translateExpr(e.Y), x, y, x, y)
				}
				return fixNumber(fmt.Sprintf("%s * %s", c.translateExpr(e.X), c.translateExpr(e.Y)), basic)
			case token.QUO:
				value := fmt.Sprintf("%s / %s", c.translateExpr(e.X), c.translateExpr(e.Y))
				if basic.Info()&types.IsInteger != 0 {
					value = "(Go$obj = " + value + `, (Go$obj === Go$obj && Go$obj !== 1/0 && Go$obj !== -1/0) ? Go$obj : Go$throwRuntimeError("integer divide by zero"))`
				}
				switch basic.Kind() {
				case types.Int, types.Uint:
					return "(" + value + " >> 0)" // cut off decimals
				default:
					return fixNumber(value, basic)
				}
			case token.REM:
				return fmt.Sprintf(`(Go$obj = %s %% %s, Go$obj === Go$obj ? Go$obj : Go$throwRuntimeError("integer divide by zero"))`, c.translateExpr(e.X), c.translateExpr(e.Y))
			case token.SHL, token.SHR:
				op := e.Op.String()
				if e.Op == token.SHR && basic.Info()&types.IsUnsigned != 0 {
					op = ">>>"
				}
				if c.info.Values[e.Y] != nil {
					return fixNumber(fmt.Sprintf("%s %s %s", c.translateExpr(e.X), op, c.translateExpr(e.Y)), basic)
				}
				if e.Op == token.SHR && basic.Info()&types.IsUnsigned == 0 {
					return fixNumber(fmt.Sprintf("(%s >> Go$min(%s, 31))", c.translateExpr(e.X), c.translateExpr(e.Y)), basic)
				}
				y := c.newVariable("y")
				return fixNumber(fmt.Sprintf("(%s = %s, %s < 32 ? (%s %s %s) : 0)", y, c.translateExprToType(e.Y, types.Typ[types.Uint]), y, c.translateExpr(e.X), op, y), basic)
			case token.AND, token.OR, token.XOR:
				return fixNumber(fmt.Sprintf("(%s %s %s)", c.translateExpr(e.X), e.Op, c.translateExpr(e.Y)), basic)
			case token.AND_NOT:
				return fixNumber(fmt.Sprintf("(%s &~ %s)", c.translateExpr(e.X), c.translateExpr(e.Y)), basic)
			default:
				panic(e.Op)
			}
		}

		switch e.Op {
		case token.ADD, token.LSS, token.LEQ, token.GTR, token.GEQ, token.LAND, token.LOR:
			return fmt.Sprintf("%s %s %s", c.translateExpr(e.X), e.Op, c.translateExpr(e.Y))
		case token.EQL:
			switch u := t.Underlying().(type) {
			case *types.Struct:
				x := c.newVariable("x")
				y := c.newVariable("y")
				var conds []string
				for i := 0; i < u.NumFields(); i++ {
					field := u.Field(i)
					if field.Name() == "_" {
						continue
					}
					conds = append(conds, c.translateExpr(&ast.BinaryExpr{
						X:  c.newIdent(x+"."+field.Name(), field.Type()),
						Op: token.EQL,
						Y:  c.newIdent(y+"."+field.Name(), field.Type()),
					}))
				}
				if len(conds) == 0 {
					conds = []string{"true"}
				}
				return fmt.Sprintf("(%s = %s, %s = %s, %s)", x, c.translateExpr(e.X), y, c.translateExpr(e.Y), strings.Join(conds, " && "))
			case *types.Interface:
				return fmt.Sprintf("Go$interfaceIsEqual(%s, %s)", c.translateExprToType(e.X, t), c.translateExprToType(e.Y, t))
			case *types.Array:
				return fmt.Sprintf("Go$arrayIsEqual(%s, %s)", c.translateExpr(e.X), c.translateExpr(e.Y))
			case *types.Pointer:
				xUnary, xIsUnary := e.X.(*ast.UnaryExpr)
				yUnary, yIsUnary := e.Y.(*ast.UnaryExpr)
				if xIsUnary && xUnary.Op == token.AND && yIsUnary && yUnary.Op == token.AND {
					xIndex, xIsIndex := xUnary.X.(*ast.IndexExpr)
					yIndex, yIsIndex := yUnary.X.(*ast.IndexExpr)
					if xIsIndex && yIsIndex {
						return fmt.Sprintf("Go$sliceIsEqual(%s, %s, %s, %s)", c.translateExpr(xIndex.X), c.flatten64(xIndex.Index), c.translateExpr(yIndex.X), c.flatten64(yIndex.Index))
					}
				}
				switch u.Elem().Underlying().(type) {
				case *types.Struct, *types.Interface:
					return c.translateExprToType(e.X, t) + " === " + c.translateExprToType(e.Y, t)
				case *types.Array:
					return fmt.Sprintf("Go$arrayIsEqual(%s, %s)", c.translateExprToType(e.X, t), c.translateExprToType(e.Y, t))
				default:
					return fmt.Sprintf("Go$pointerIsEqual(%s, %s)", c.translateExprToType(e.X, t), c.translateExprToType(e.Y, t))
				}
			default:
				return c.translateExprToType(e.X, t) + " === " + c.translateExprToType(e.Y, t)
			}
		default:
			panic(e.Op)
		}

	case *ast.ParenExpr:
		return fmt.Sprintf("(%s)", c.translateExpr(e.X))

	case *ast.IndexExpr:
		xType := c.info.Types[e.X]
		if ptr, isPointer := xType.(*types.Pointer); isPointer {
			xType = ptr.Elem()
		}
		switch t := xType.Underlying().(type) {
		case *types.Array:
			return fmt.Sprintf("%s[%s]", c.translateExpr(e.X), c.flatten64(e.Index))
		case *types.Slice:
			sliceVar := c.newVariable("_slice")
			indexVar := c.newVariable("_index")
			return fmt.Sprintf(`(%s = %s, %s = %s, (%s >= 0 && %s < %s.length) ? %s.array[%s.offset + %s] : Go$throwRuntimeError("index out of range"))`, sliceVar, c.translateExpr(e.X), indexVar, c.flatten64(e.Index), indexVar, indexVar, sliceVar, sliceVar, sliceVar, indexVar)
		case *types.Map:
			key := c.makeKey(e.Index, t.Key())
			if _, isTuple := exprType.(*types.Tuple); isTuple {
				return fmt.Sprintf(`(Go$obj = (%s || false)[%s], Go$obj !== undefined ? [Go$obj.v, true] : [%s, false])`, c.translateExpr(e.X), key, c.zeroValue(t.Elem()))
			}
			return fmt.Sprintf(`(Go$obj = (%s || false)[%s], Go$obj !== undefined ? Go$obj.v : %s)`, c.translateExpr(e.X), key, c.zeroValue(t.Elem()))
		case *types.Basic:
			return fmt.Sprintf("%s.charCodeAt(%s)", c.translateExpr(e.X), c.flatten64(e.Index))
		default:
			panic(fmt.Sprintf("Unhandled IndexExpr: %T\n", t))
		}

	case *ast.SliceExpr:
		b, isBasic := c.info.Types[e.X].(*types.Basic)
		isString := isBasic && b.Info()&types.IsString != 0
		slice := c.translateExprToType(e.X, exprType)
		if e.High == nil {
			if e.Low == nil {
				return slice
			}
			if isString {
				return fmt.Sprintf("%s.substring(%s)", slice, c.flatten64(e.Low))
			}
			return fmt.Sprintf("Go$subslice(%s, %s)", slice, c.flatten64(e.Low))
		}
		low := "0"
		if e.Low != nil {
			low = c.flatten64(e.Low)
		}
		if isString {
			return fmt.Sprintf("%s.substring(%s, %s)", slice, low, c.flatten64(e.High))
		}
		if e.Max != nil {
			return fmt.Sprintf("Go$subslice(%s, %s, %s, %s)", slice, low, c.flatten64(e.High), c.flatten64(e.Max))
		}
		return fmt.Sprintf("Go$subslice(%s, %s, %s)", slice, low, c.flatten64(e.High))

	case *ast.SelectorExpr:
		sel := c.info.Selections[e]
		parameterName := func(v *types.Var) string {
			if v.Anonymous() || v.Name() == "" {
				return c.newVariable("param")
			}
			return c.newVariable(v.Name())
		}
		makeParametersList := func() []string {
			params := sel.Obj().Type().(*types.Signature).Params()
			names := make([]string, params.Len())
			for i := 0; i < params.Len(); i++ {
				names[i] = parameterName(params.At(i))
			}
			return names
		}

		switch sel.Kind() {
		case types.FieldVal:
			return c.translateExpr(e.X) + "." + translateSelection(sel)
		case types.MethodVal:
			parameters := makeParametersList()
			recv := c.newVariable("_recv")
			return fmt.Sprintf("(%s = %s, function(%s) { return %s.%s(%s); })", recv, c.translateExpr(e.X), strings.Join(parameters, ", "), recv, e.Sel.Name, strings.Join(parameters, ", "))
		case types.MethodExpr:
			recv := "recv"
			if isWrapped(sel.Recv()) {
				recv = fmt.Sprintf("(new %s(recv))", c.typeName(sel.Recv()))
			}
			parameters := makeParametersList()
			return fmt.Sprintf("(function(%s) { return %s.%s(%s); })", strings.Join(append([]string{"recv"}, parameters...), ", "), recv, sel.Obj().(*types.Func).Name(), strings.Join(parameters, ", "))
		case types.PackageObj:
			return fmt.Sprintf("%s.%s", c.translateExpr(e.X), e.Sel.Name)
		}
		panic("")

	case *ast.CallExpr:
		plainFun := e.Fun
		for {
			if p, isParen := plainFun.(*ast.ParenExpr); isParen {
				plainFun = p.X
				continue
			}
			break
		}

		switch f := plainFun.(type) {
		case *ast.Ident:
			switch o := c.info.Objects[f].(type) {
			case *types.Builtin:
				switch o.Name() {
				case "new":
					t := c.info.Types[e].(*types.Pointer)
					if types.IsIdentical(t.Elem().Underlying(), types.Typ[types.Uintptr]) {
						return "new Uint8Array(8)"
					}
					switch t.Elem().Underlying().(type) {
					case *types.Struct, *types.Array:
						return c.zeroValue(t.Elem())
					default:
						return fmt.Sprintf("Go$newDataPointer(%s, %s)", c.zeroValue(t.Elem()), c.typeName(t))
					}
				case "make":
					switch t2 := c.info.Types[e.Args[0]].Underlying().(type) {
					case *types.Slice:
						if len(e.Args) == 3 {
							return fmt.Sprintf("Go$subslice(new %s(Go$makeArray(%s, %s, function() { return %s; })), 0, %s)", c.typeName(c.info.Types[e.Args[0]]), toArrayType(t2.Elem()), c.translateExprToType(e.Args[2], types.Typ[types.Int]), c.zeroValue(t2.Elem()), c.translateExprToType(e.Args[1], types.Typ[types.Int]))
						}
						return fmt.Sprintf("new %s(Go$makeArray(%s, %s, function() { return %s; }))", c.typeName(c.info.Types[e.Args[0]]), toArrayType(t2.Elem()), c.translateExprToType(e.Args[1], types.Typ[types.Int]), c.zeroValue(t2.Elem()))
					default:
						args := []string{"undefined"}
						for _, arg := range e.Args[1:] {
							args = append(args, c.translateExpr(arg))
						}
						return fmt.Sprintf("new %s(%s)", c.typeName(c.info.Types[e.Args[0]]), strings.Join(args, ", "))
					}
				case "len":
					arg := c.translateExpr(e.Args[0])
					switch argType := c.info.Types[e.Args[0]].Underlying().(type) {
					case *types.Basic, *types.Slice:
						return arg + ".length"
					case *types.Pointer:
						return fmt.Sprintf("(%s, %d)", arg, argType.Elem().(*types.Array).Len())
					case *types.Map:
						return fmt.Sprintf("(Go$obj = %s, Go$obj !== null ? Go$keys(Go$obj).length : 0)", arg)
					case *types.Chan:
						return "0"
					// length of array is constant
					default:
						panic(fmt.Sprintf("Unhandled len type: %T\n", argType))
					}
				case "cap":
					arg := c.translateExpr(e.Args[0])
					switch argType := c.info.Types[e.Args[0]].Underlying().(type) {
					case *types.Slice:
						return arg + ".capacity"
					case *types.Pointer:
						return fmt.Sprintf("(%s, %d)", arg, argType.Elem().(*types.Array).Len())
					case *types.Chan:
						return "0"
					// capacity of array is constant
					default:
						panic(fmt.Sprintf("Unhandled cap type: %T\n", argType))
					}
				case "panic":
					return fmt.Sprintf("throw new Go$Panic(%s)", c.translateExprToType(e.Args[0], types.NewInterface(nil, nil)))
				case "append":
					if e.Ellipsis.IsValid() {
						return fmt.Sprintf("Go$append(%s, %s)", c.translateExpr(e.Args[0]), c.translateExprToType(e.Args[1], exprType))
					}
					sliceType := exprType.Underlying().(*types.Slice)
					toAppend := createListComposite(sliceType.Elem(), c.translateExprSlice(e.Args[1:], sliceType.Elem()))
					return fmt.Sprintf("Go$append(%s, new %s(%s))", c.translateExpr(e.Args[0]), c.typeName(exprType), toAppend)
				case "delete":
					return fmt.Sprintf(`delete (%s || Go$Map.Go$nil)[%s]`, c.translateExpr(e.Args[0]), c.makeKey(e.Args[1], c.info.Types[e.Args[0]].Underlying().(*types.Map).Key()))
				case "copy":
					return fmt.Sprintf("Go$copy(%s, %s)", c.translateExprToType(e.Args[0], types.NewSlice(types.Typ[types.Byte])), c.translateExprToType(e.Args[1], types.NewSlice(types.Typ[types.Byte])))
				case "print", "println":
					return fmt.Sprintf("console.log(%s)", strings.Join(c.translateExprSlice(e.Args, nil), ", "))
				case "complex":
					return fmt.Sprintf("new %s(%s, %s)", c.typeName(c.info.Types[e]), c.translateExpr(e.Args[0]), c.translateExpr(e.Args[1]))
				case "real":
					return c.translateExpr(e.Args[0]) + ".real"
				case "imag":
					return c.translateExpr(e.Args[0]) + ".imag"
				case "recover":
					return "Go$recover()"
				case "close":
					return `Go$throwRuntimeError("not supported by GopherJS: close")`
				default:
					panic(fmt.Sprintf("Unhandled builtin: %s\n", o.Name()))
				}
			case *types.TypeName: // conversion
				if basic, isBasic := o.Type().Underlying().(*types.Basic); isBasic && !types.IsIdentical(c.info.Types[e.Args[0]], types.Typ[types.UnsafePointer]) {
					return fixNumber(c.translateExprToType(e.Args[0], o.Type()), basic)
				}
				return c.translateExprToType(e.Args[0], o.Type())
			}
		case *ast.FuncType: // conversion
			return c.translateExprToType(e.Args[0], c.info.Types[plainFun])
		}

		funType := c.info.Types[plainFun]
		sig, isSig := funType.Underlying().(*types.Signature)
		if !isSig { // conversion
			if c.pkg.Path() == "reflect" {
				if call, isCall := e.Args[0].(*ast.CallExpr); isCall && types.IsIdentical(c.info.Types[call.Fun], types.Typ[types.UnsafePointer]) {
					if named, isNamed := funType.(*types.Pointer).Elem().(*types.Named); isNamed {
						return c.translateExpr(call.Args[0]) + "." + named.Obj().Name() // unsafe conversion
					}
				}
			}
			return c.translateExprToType(e.Args[0], funType)
		}

		var fun string
		switch f := plainFun.(type) {
		case *ast.SelectorExpr:
			sel := c.info.Selections[f]

			switch sel.Kind() {
			case types.MethodVal:
				methodsRecvType := sel.Obj().(*types.Func).Type().(*types.Signature).Recv().Type()
				_, pointerExpected := methodsRecvType.(*types.Pointer)
				_, isPointer := sel.Recv().Underlying().(*types.Pointer)
				_, isStruct := sel.Recv().Underlying().(*types.Struct)
				_, isArray := sel.Recv().Underlying().(*types.Array)
				if pointerExpected && !isPointer && !isStruct && !isArray {
					target := c.translateExpr(f.X)
					vVar := c.newVariable("v")
					fun = fmt.Sprintf("(new %s(function() { return %s; }, function(%s) { %s = %s; })).%s", c.typeName(methodsRecvType), target, vVar, target, vVar, f.Sel.Name)
					break
				}
				if isWrapped(sel.Recv()) {
					fun = fmt.Sprintf("(new %s(%s)).%s", c.typeName(sel.Recv()), c.translateExpr(f.X), f.Sel.Name)
					break
				}
				fun = fmt.Sprintf("%s.%s", c.translateExpr(f.X), f.Sel.Name)
			case types.FieldVal, types.MethodExpr, types.PackageObj:
				fun = c.translateExpr(f)
			default:
				panic("")
			}
		default:
			fun = c.translateExpr(plainFun)
		}
		if len(e.Args) == 1 {
			if tuple, isTuple := c.info.Types[e.Args[0]].(*types.Tuple); isTuple {
				args := make([]ast.Expr, tuple.Len())
				for i := range args {
					args[i] = c.newIdent(fmt.Sprintf("Go$tuple[%d]", i), tuple.At(i).Type())
				}
				return fmt.Sprintf("(Go$tuple = %s, %s(%s))", c.translateExpr(e.Args[0]), fun, c.translateArgs(sig, args, false))
			}
		}
		return fmt.Sprintf("%s(%s)", fun, c.translateArgs(sig, e.Args, e.Ellipsis.IsValid()))

	case *ast.StarExpr:
		if c1, isCall := e.X.(*ast.CallExpr); isCall && len(c1.Args) == 1 {
			if c2, isCall := c1.Args[0].(*ast.CallExpr); isCall && len(c2.Args) == 1 && types.IsIdentical(c.info.Types[c2.Fun], types.Typ[types.UnsafePointer]) {
				if unary, isUnary := c2.Args[0].(*ast.UnaryExpr); isUnary && unary.Op == token.AND {
					return c.translateExpr(unary.X) // unsafe conversion
				}
			}
		}
		switch exprType.Underlying().(type) {
		case *types.Struct, *types.Array:
			return c.translateExpr(e.X)
		}
		return c.translateExpr(e.X) + ".Go$get()"

	case *ast.TypeAssertExpr:
		if e.Type == nil {
			return c.translateExpr(e.X)
		}
		t := c.info.Types[e.Type]
		check := "Go$obj !== null && " + c.typeCheck("Go$obj.constructor", t)
		value := "Go$obj"
		if _, isInterface := t.Underlying().(*types.Interface); !isInterface {
			value += ".Go$val"
		}
		if _, isTuple := exprType.(*types.Tuple); isTuple {
			return fmt.Sprintf("(Go$obj = %s, %s ? [%s, true] : [%s, false])", c.translateExpr(e.X), check, value, c.zeroValue(c.info.Types[e.Type]))
		}
		return fmt.Sprintf("(Go$obj = %s, %s ? %s : Go$typeAssertionFailed(Go$obj))", c.translateExpr(e.X), check, value)

	case *ast.Ident:
		if e.Name == "_" {
			panic("Tried to translate underscore identifier.")
		}
		switch o := c.info.Objects[e].(type) {
		case *types.PkgName:
			return c.pkgVars[o.Pkg().Path()]
		case *types.Var, *types.Const:
			return c.objectName(o)
		case *types.Func:
			return c.objectName(o)
		case *types.TypeName:
			return c.typeName(o.Type())
		case *types.Nil:
			return c.zeroValue(c.info.Types[e])
		case nil:
			return e.Name
		default:
			panic(fmt.Sprintf("Unhandled object: %T\n", o))
		}

	case nil:
		return ""

	default:
		panic(fmt.Sprintf("Unhandled expression: %T\n", e))

	}
}
Esempio n. 14
0
func Write(pkg *types.Package, out io.Writer, sizes types.Sizes) {
	fmt.Fprintf(out, "package %s\n", pkg.Name())

	e := &exporter{pkg: pkg, imports: make(map[*types.Package]bool), out: out}

	for _, imp := range pkg.Imports() {
		e.addImport(imp)
	}

	for _, name := range pkg.Scope().Names() {
		obj := pkg.Scope().Lookup(name)

		_, isTypeName := obj.(*types.TypeName)
		if obj.Exported() || isTypeName {
			e.toExport = append(e.toExport, obj)
		}
	}

	for i := 0; i < len(e.toExport); i++ {
		switch o := e.toExport[i].(type) {
		case *types.TypeName:
			fmt.Fprintf(out, "type %s %s\n", e.makeName(o), e.makeType(o.Type().Underlying()))
			if _, isInterface := o.Type().Underlying().(*types.Interface); !isInterface {
				writeMethods := func(t types.Type) {
					methods := types.NewMethodSet(t)
					for i := 0; i < methods.Len(); i++ {
						m := methods.At(i)
						if len(m.Index()) > 1 {
							continue // method of embedded field
						}
						out.Write([]byte("func (? " + e.makeType(m.Recv()) + ") " + e.makeName(m.Obj()) + e.makeSignature(m.Type()) + "\n"))
					}
				}
				writeMethods(o.Type())
				writeMethods(types.NewPointer(o.Type()))
			}
		case *types.Func:
			out.Write([]byte("func " + e.makeName(o) + e.makeSignature(o.Type()) + "\n"))
		case *types.Const:
			optType := ""
			basic, isBasic := o.Type().(*types.Basic)
			if !isBasic || basic.Info()&types.IsUntyped == 0 {
				optType = " " + e.makeType(o.Type())
			}

			basic = o.Type().Underlying().(*types.Basic)
			var val string
			switch {
			case basic.Info()&types.IsBoolean != 0:
				val = strconv.FormatBool(exact.BoolVal(o.Val()))
			case basic.Info()&types.IsInteger != 0:
				if basic.Kind() == types.Uint64 {
					d, _ := exact.Uint64Val(o.Val())
					val = fmt.Sprintf("%#x", d)
					break
				}
				d, _ := exact.Int64Val(o.Val())
				if basic.Kind() == types.UntypedRune {
					switch {
					case d < 0 || d > unicode.MaxRune:
						val = fmt.Sprintf("('\\x00' + %d)", d)
					case d > 0xffff:
						val = fmt.Sprintf("'\\U%08x'", d)
					default:
						val = fmt.Sprintf("'\\u%04x'", d)
					}
					break
				}
				val = fmt.Sprintf("%#x", d)
			case basic.Info()&types.IsFloat != 0:
				f, _ := exact.Float64Val(o.Val())
				val = strconv.FormatFloat(f, 'b', -1, 64)
			case basic.Info()&types.IsComplex != 0:
				r, _ := exact.Float64Val(exact.Real(o.Val()))
				i, _ := exact.Float64Val(exact.Imag(o.Val()))
				val = fmt.Sprintf("(%s+%si)", strconv.FormatFloat(r, 'b', -1, 64), strconv.FormatFloat(i, 'b', -1, 64))
			case basic.Info()&types.IsString != 0:
				val = fmt.Sprintf("%#v", exact.StringVal(o.Val()))
			default:
				panic("Unhandled constant type: " + basic.String())
			}
			out.Write([]byte("const " + e.makeName(o) + optType + " = " + val + "\n"))
		case *types.Var:
			out.Write([]byte("var " + e.makeName(o) + " " + e.makeType(o.Type()) + "\n"))
		default:
			panic(fmt.Sprintf("Unhandled object: %T\n", o))
		}
	}

	fmt.Fprintf(out, "$$\n")
}
Esempio n. 15
0
func (c *funcContext) translateExpr(expr ast.Expr) *expression {
	exprType := c.p.info.Types[expr].Type
	if value := c.p.info.Types[expr].Value; value != nil {
		basic := types.Typ[types.String]
		if value.Kind() != exact.String { // workaround for bug in go/types
			basic = exprType.Underlying().(*types.Basic)
		}
		switch {
		case basic.Info()&types.IsBoolean != 0:
			return c.formatExpr("%s", strconv.FormatBool(exact.BoolVal(value)))
		case basic.Info()&types.IsInteger != 0:
			if is64Bit(basic) {
				d, _ := exact.Uint64Val(value)
				if basic.Kind() == types.Int64 {
					return c.formatExpr("new %s(%s, %s)", c.typeName(exprType), strconv.FormatInt(int64(d)>>32, 10), strconv.FormatUint(d&(1<<32-1), 10))
				}
				return c.formatExpr("new %s(%s, %s)", c.typeName(exprType), strconv.FormatUint(d>>32, 10), strconv.FormatUint(d&(1<<32-1), 10))
			}
			d, _ := exact.Int64Val(value)
			return c.formatExpr("%s", strconv.FormatInt(d, 10))
		case basic.Info()&types.IsFloat != 0:
			f, _ := exact.Float64Val(value)
			return c.formatExpr("%s", strconv.FormatFloat(f, 'g', -1, 64))
		case basic.Info()&types.IsComplex != 0:
			r, _ := exact.Float64Val(exact.Real(value))
			i, _ := exact.Float64Val(exact.Imag(value))
			if basic.Kind() == types.UntypedComplex {
				exprType = types.Typ[types.Complex128]
			}
			return c.formatExpr("new %s(%s, %s)", c.typeName(exprType), strconv.FormatFloat(r, 'g', -1, 64), strconv.FormatFloat(i, 'g', -1, 64))
		case basic.Info()&types.IsString != 0:
			return c.formatExpr("%s", encodeString(exact.StringVal(value)))
		default:
			panic("Unhandled constant type: " + basic.String())
		}
	}

	switch e := expr.(type) {
	case *ast.CompositeLit:
		if ptrType, isPointer := exprType.(*types.Pointer); isPointer {
			exprType = ptrType.Elem()
		}

		collectIndexedElements := func(elementType types.Type) []string {
			elements := make([]string, 0)
			i := 0
			zero := c.zeroValue(elementType)
			for _, element := range e.Elts {
				if kve, isKve := element.(*ast.KeyValueExpr); isKve {
					key, _ := exact.Int64Val(c.p.info.Types[kve.Key].Value)
					i = int(key)
					element = kve.Value
				}
				for len(elements) <= i {
					elements = append(elements, zero)
				}
				elements[i] = c.translateImplicitConversion(element, elementType).String()
				i++
			}
			return elements
		}

		switch t := exprType.Underlying().(type) {
		case *types.Array:
			elements := collectIndexedElements(t.Elem())
			if len(elements) != 0 {
				zero := c.zeroValue(t.Elem())
				for len(elements) < int(t.Len()) {
					elements = append(elements, zero)
				}
				return c.formatExpr(`go$toNativeArray("%s", [%s])`, typeKind(t.Elem()), strings.Join(elements, ", "))
			}
			return c.formatExpr(`go$makeNativeArray("%s", %d, function() { return %s; })`, typeKind(t.Elem()), int(t.Len()), c.zeroValue(t.Elem()))
		case *types.Slice:
			return c.formatExpr("new %s([%s])", c.typeName(exprType), strings.Join(collectIndexedElements(t.Elem()), ", "))
		case *types.Map:
			mapVar := c.newVariable("_map")
			keyVar := c.newVariable("_key")
			assignments := ""
			for _, element := range e.Elts {
				kve := element.(*ast.KeyValueExpr)
				assignments += c.formatExpr(`%s = %s, %s[%s] = { k: %s, v: %s }, `, keyVar, c.translateImplicitConversion(kve.Key, t.Key()), mapVar, c.makeKey(c.newIdent(keyVar, t.Key()), t.Key()), keyVar, c.translateImplicitConversion(kve.Value, t.Elem())).String()
			}
			return c.formatExpr("(%s = new Go$Map(), %s%s)", mapVar, assignments, mapVar)
		case *types.Struct:
			elements := make([]string, t.NumFields())
			isKeyValue := true
			if len(e.Elts) != 0 {
				_, isKeyValue = e.Elts[0].(*ast.KeyValueExpr)
			}
			if !isKeyValue {
				for i, element := range e.Elts {
					elements[i] = c.translateImplicitConversion(element, t.Field(i).Type()).String()
				}
			}
			if isKeyValue {
				for i := range elements {
					elements[i] = c.zeroValue(t.Field(i).Type())
				}
				for _, element := range e.Elts {
					kve := element.(*ast.KeyValueExpr)
					for j := range elements {
						if kve.Key.(*ast.Ident).Name == t.Field(j).Name() {
							elements[j] = c.translateImplicitConversion(kve.Value, t.Field(j).Type()).String()
							break
						}
					}
				}
			}
			return c.formatExpr("new %s.Ptr(%s)", c.typeName(exprType), strings.Join(elements, ", "))
		default:
			panic(fmt.Sprintf("Unhandled CompositeLit type: %T\n", t))
		}

	case *ast.FuncLit:
		params, body := c.translateFunction(e.Type, exprType.(*types.Signature), e.Body.List)
		if len(c.escapingVars) != 0 {
			list := strings.Join(c.escapingVars, ", ")
			return c.formatExpr("(function(%s) { return function(%s) {\n%s%s}; })(%s)", list, strings.Join(params, ", "), string(body), strings.Repeat("\t", c.p.indentation), list)
		}
		return c.formatExpr("(function(%s) {\n%s%s})", strings.Join(params, ", "), string(body), strings.Repeat("\t", c.p.indentation))

	case *ast.UnaryExpr:
		switch e.Op {
		case token.AND:
			switch c.p.info.Types[e.X].Type.Underlying().(type) {
			case *types.Struct, *types.Array:
				return c.translateExpr(e.X)
			default:
				if _, isComposite := e.X.(*ast.CompositeLit); isComposite {
					return c.formatExpr("go$newDataPointer(%e, %s)", e.X, c.typeName(c.p.info.Types[e].Type))
				}
				closurePrefix := ""
				closureSuffix := ""
				if len(c.escapingVars) != 0 {
					list := strings.Join(c.escapingVars, ", ")
					closurePrefix = "(function(" + list + ") { return "
					closureSuffix = "; })(" + list + ")"
				}
				vVar := c.newVariable("v")
				return c.formatExpr("%snew %s(function() { return %e; }, function(%s) { %s; })%s", closurePrefix, c.typeName(exprType), e.X, vVar, c.translateAssign(e.X, vVar), closureSuffix)
			}
		case token.ARROW:
			return c.formatExpr("undefined")
		}

		t := c.p.info.Types[e.X].Type
		basic := t.Underlying().(*types.Basic)
		switch e.Op {
		case token.ADD:
			return c.translateExpr(e.X)
		case token.SUB:
			switch {
			case is64Bit(basic):
				return c.formatExpr("new %1s(-%2h, -%2l)", c.typeName(t), e.X)
			case basic.Info()&types.IsComplex != 0:
				return c.formatExpr("new %1s(-%2r, -%2i)", c.typeName(t), e.X)
			case basic.Info()&types.IsUnsigned != 0:
				return c.fixNumber(c.formatExpr("-%e", e.X), basic)
			default:
				return c.formatExpr("-%e", e.X)
			}
		case token.XOR:
			if is64Bit(basic) {
				return c.formatExpr("new %1s(~%2h, ~%2l >>> 0)", c.typeName(t), e.X)
			}
			return c.fixNumber(c.formatExpr("~%e", e.X), basic)
		case token.NOT:
			x := c.translateExpr(e.X)
			if x.String() == "true" {
				return c.formatExpr("false")
			}
			if x.String() == "false" {
				return c.formatExpr("true")
			}
			return c.formatExpr("!%s", x)
		default:
			panic(e.Op)
		}

	case *ast.BinaryExpr:
		if e.Op == token.NEQ {
			return c.formatExpr("!(%s)", c.translateExpr(&ast.BinaryExpr{
				X:  e.X,
				Op: token.EQL,
				Y:  e.Y,
			}))
		}

		t := c.p.info.Types[e.X].Type
		t2 := c.p.info.Types[e.Y].Type
		_, isInterface := t2.Underlying().(*types.Interface)
		if isInterface {
			t = t2
		}

		if basic, isBasic := t.Underlying().(*types.Basic); isBasic && basic.Info()&types.IsNumeric != 0 {
			if is64Bit(basic) {
				switch e.Op {
				case token.MUL:
					return c.formatExpr("go$mul64(%e, %e)", e.X, e.Y)
				case token.QUO:
					return c.formatExpr("go$div64(%e, %e, false)", e.X, e.Y)
				case token.REM:
					return c.formatExpr("go$div64(%e, %e, true)", e.X, e.Y)
				case token.SHL:
					return c.formatExpr("go$shiftLeft64(%e, %f)", e.X, e.Y)
				case token.SHR:
					return c.formatExpr("go$shiftRight%s(%e, %f)", toJavaScriptType(basic), e.X, e.Y)
				case token.EQL:
					return c.formatExpr("(%1h === %2h && %1l === %2l)", e.X, e.Y)
				case token.LSS:
					return c.formatExpr("(%1h < %2h || (%1h === %2h && %1l < %2l))", e.X, e.Y)
				case token.LEQ:
					return c.formatExpr("(%1h < %2h || (%1h === %2h && %1l <= %2l))", e.X, e.Y)
				case token.GTR:
					return c.formatExpr("(%1h > %2h || (%1h === %2h && %1l > %2l))", e.X, e.Y)
				case token.GEQ:
					return c.formatExpr("(%1h > %2h || (%1h === %2h && %1l >= %2l))", e.X, e.Y)
				case token.ADD, token.SUB:
					return c.formatExpr("new %3s(%1h %4t %2h, %1l %4t %2l)", e.X, e.Y, c.typeName(t), e.Op)
				case token.AND, token.OR, token.XOR:
					return c.formatExpr("new %3s(%1h %4t %2h, (%1l %4t %2l) >>> 0)", e.X, e.Y, c.typeName(t), e.Op)
				case token.AND_NOT:
					return c.formatExpr("new %3s(%1h &~ %2h, (%1l &~ %2l) >>> 0)", e.X, e.Y, c.typeName(t))
				default:
					panic(e.Op)
				}
			}

			if basic.Info()&types.IsComplex != 0 {
				switch e.Op {
				case token.EQL:
					if basic.Kind() == types.Complex64 {
						return c.formatExpr("(go$float32IsEqual(%1r, %2r) && go$float32IsEqual(%1i, %2i))", e.X, e.Y)
					}
					return c.formatExpr("(%1r === %2r && %1i === %2i)", e.X, e.Y)
				case token.ADD, token.SUB:
					return c.formatExpr("new %3s(%1r %4t %2r, %1i %4t %2i)", e.X, e.Y, c.typeName(t), e.Op)
				case token.MUL:
					return c.formatExpr("new %3s(%1r * %2r - %1i * %2i, %1r * %2i + %1i * %2r)", e.X, e.Y, c.typeName(t))
				case token.QUO:
					return c.formatExpr("go$divComplex(%e, %e)", e.X, e.Y)
				default:
					panic(e.Op)
				}
			}

			switch e.Op {
			case token.EQL:
				if basic.Kind() == types.Float32 {
					return c.formatParenExpr("go$float32IsEqual(%e, %e)", e.X, e.Y)
				}
				return c.formatParenExpr("%e === %e", e.X, e.Y)
			case token.LSS, token.LEQ, token.GTR, token.GEQ:
				return c.formatExpr("%e %t %e", e.X, e.Op, e.Y)
			case token.ADD, token.SUB:
				if basic.Info()&types.IsInteger != 0 {
					return c.fixNumber(c.formatExpr("%e %t %e", e.X, e.Op, e.Y), basic)
				}
				return c.formatExpr("%e %t %e", e.X, e.Op, e.Y)
			case token.MUL:
				switch basic.Kind() {
				case types.Int32, types.Int:
					return c.formatParenExpr("(((%1e >>> 16 << 16) * %2e >> 0) + (%1e << 16 >>> 16) * %2e) >> 0", e.X, e.Y)
				case types.Uint32, types.Uint, types.Uintptr:
					return c.formatParenExpr("(((%1e >>> 16 << 16) * %2e >>> 0) + (%1e << 16 >>> 16) * %2e) >>> 0", e.X, e.Y)
				case types.Float32, types.Float64:
					return c.formatExpr("%e * %e", e.X, e.Y)
				default:
					return c.fixNumber(c.formatExpr("%e * %e", e.X, e.Y), basic)
				}
			case token.QUO:
				if basic.Info()&types.IsInteger != 0 {
					// cut off decimals
					shift := ">>"
					if basic.Info()&types.IsUnsigned != 0 {
						shift = ">>>"
					}
					return c.formatExpr(`(%1s = %2e / %3e, (%1s === %1s && %1s !== 1/0 && %1s !== -1/0) ? %1s %4s 0 : go$throwRuntimeError("integer divide by zero"))`, c.newVariable("_q"), e.X, e.Y, shift)
				}
				return c.formatExpr("%e / %e", e.X, e.Y)
			case token.REM:
				return c.formatExpr(`(%1s = %2e %% %3e, %1s === %1s ? %1s : go$throwRuntimeError("integer divide by zero"))`, c.newVariable("_r"), e.X, e.Y)
			case token.SHL, token.SHR:
				op := e.Op.String()
				if e.Op == token.SHR && basic.Info()&types.IsUnsigned != 0 {
					op = ">>>"
				}
				if c.p.info.Types[e.Y].Value != nil {
					return c.fixNumber(c.formatExpr("%e %s %e", e.X, op, e.Y), basic)
				}
				if e.Op == token.SHR && basic.Info()&types.IsUnsigned == 0 {
					return c.fixNumber(c.formatParenExpr("%e >> go$min(%e, 31)", e.X, e.Y), basic)
				}
				y := c.newVariable("y")
				return c.fixNumber(c.formatExpr("(%s = %s, %s < 32 ? (%e %s %s) : 0)", y, c.translateImplicitConversion(e.Y, types.Typ[types.Uint]), y, e.X, op, y), basic)
			case token.AND, token.OR:
				if basic.Info()&types.IsUnsigned != 0 {
					return c.formatParenExpr("(%e %t %e) >>> 0", e.X, e.Op, e.Y)
				}
				return c.formatParenExpr("%e %t %e", e.X, e.Op, e.Y)
			case token.AND_NOT:
				return c.formatParenExpr("%e & ~%e", e.X, e.Y)
			case token.XOR:
				return c.fixNumber(c.formatParenExpr("%e ^ %e", e.X, e.Y), basic)
			default:
				panic(e.Op)
			}
		}

		switch e.Op {
		case token.ADD, token.LSS, token.LEQ, token.GTR, token.GEQ:
			return c.formatExpr("%e %t %e", e.X, e.Op, e.Y)
		case token.LAND:
			x := c.translateExpr(e.X)
			y := c.translateExpr(e.Y)
			if x.String() == "false" {
				return c.formatExpr("false")
			}
			return c.formatExpr("%s && %s", x, y)
		case token.LOR:
			x := c.translateExpr(e.X)
			y := c.translateExpr(e.Y)
			if x.String() == "true" {
				return c.formatExpr("true")
			}
			return c.formatExpr("%s || %s", x, y)
		case token.EQL:
			switch u := t.Underlying().(type) {
			case *types.Struct:
				x := c.newVariable("x")
				y := c.newVariable("y")
				var conds []string
				for i := 0; i < u.NumFields(); i++ {
					field := u.Field(i)
					if field.Name() == "_" {
						continue
					}
					conds = append(conds, c.translateExpr(&ast.BinaryExpr{
						X:  c.newIdent(x+"."+fieldName(u, i), field.Type()),
						Op: token.EQL,
						Y:  c.newIdent(y+"."+fieldName(u, i), field.Type()),
					}).String())
				}
				if len(conds) == 0 {
					conds = []string{"true"}
				}
				return c.formatExpr("(%s = %e, %s = %e, %s)", x, e.X, y, e.Y, strings.Join(conds, " && "))
			case *types.Interface:
				if isJsObject(t) {
					return c.formatExpr("%s === %s", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
				}
				return c.formatExpr("go$interfaceIsEqual(%s, %s)", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
			case *types.Array:
				return c.formatExpr("go$arrayIsEqual(%e, %e)", e.X, e.Y)
			case *types.Pointer:
				xUnary, xIsUnary := e.X.(*ast.UnaryExpr)
				yUnary, yIsUnary := e.Y.(*ast.UnaryExpr)
				if xIsUnary && xUnary.Op == token.AND && yIsUnary && yUnary.Op == token.AND {
					xIndex, xIsIndex := xUnary.X.(*ast.IndexExpr)
					yIndex, yIsIndex := yUnary.X.(*ast.IndexExpr)
					if xIsIndex && yIsIndex {
						return c.formatExpr("go$sliceIsEqual(%e, %f, %e, %f)", xIndex.X, xIndex.Index, yIndex.X, yIndex.Index)
					}
				}
				switch u.Elem().Underlying().(type) {
				case *types.Struct, *types.Interface:
					return c.formatExpr("%s === %s", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
				case *types.Array:
					return c.formatExpr("go$arrayIsEqual(%s, %s)", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
				default:
					return c.formatExpr("go$pointerIsEqual(%s, %s)", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
				}
			default:
				return c.formatExpr("%s === %s", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
			}
		default:
			panic(e.Op)
		}

	case *ast.ParenExpr:
		x := c.translateExpr(e.X)
		if x.String() == "true" || x.String() == "false" {
			return x
		}
		return c.formatParenExpr("%s", x)

	case *ast.IndexExpr:
		switch t := c.p.info.Types[e.X].Type.Underlying().(type) {
		case *types.Array, *types.Pointer:
			return c.formatExpr("%e[%f]", e.X, e.Index)
		case *types.Slice:
			return c.formatExpr(`((%2f < 0 || %2f >= %1e.length) ? go$throwRuntimeError("index out of range") : %1e.array[%1e.offset + %2f])`, e.X, e.Index)
		case *types.Map:
			key := c.makeKey(e.Index, t.Key())
			if _, isTuple := exprType.(*types.Tuple); isTuple {
				return c.formatExpr(`(%1s = %2e[%3s], %1s !== undefined ? [%1s.v, true] : [%4s, false])`, c.newVariable("_entry"), e.X, key, c.zeroValue(t.Elem()))
			}
			return c.formatExpr(`(%1s = %2e[%3s], %1s !== undefined ? %1s.v : %4s)`, c.newVariable("_entry"), e.X, key, c.zeroValue(t.Elem()))
		case *types.Basic:
			return c.formatExpr("%e.charCodeAt(%f)", e.X, e.Index)
		default:
			panic(fmt.Sprintf("Unhandled IndexExpr: %T\n", t))
		}

	case *ast.SliceExpr:
		if b, isBasic := c.p.info.Types[e.X].Type.Underlying().(*types.Basic); isBasic && b.Info()&types.IsString != 0 {
			switch {
			case e.Low == nil && e.High == nil:
				return c.translateExpr(e.X)
			case e.Low == nil:
				return c.formatExpr("%e.substring(0, %f)", e.X, e.High)
			case e.High == nil:
				return c.formatExpr("%e.substring(%f)", e.X, e.Low)
			default:
				return c.formatExpr("%e.substring(%f, %f)", e.X, e.Low, e.High)
			}
		}
		slice := c.translateConversionToSlice(e.X, exprType)
		switch {
		case e.Low == nil && e.High == nil:
			return c.formatExpr("%s", slice)
		case e.Low == nil:
			if e.Max != nil {
				return c.formatExpr("go$subslice(%s, 0, %f, %f)", slice, e.High, e.Max)
			}
			return c.formatExpr("go$subslice(%s, 0, %f)", slice, e.High)
		case e.High == nil:
			return c.formatExpr("go$subslice(%s, %f)", slice, e.Low)
		default:
			if e.Max != nil {
				return c.formatExpr("go$subslice(%s, %f, %f, %f)", slice, e.Low, e.High, e.Max)
			}
			return c.formatExpr("go$subslice(%s, %f, %f)", slice, e.Low, e.High)
		}

	case *ast.SelectorExpr:
		sel := c.p.info.Selections[e]
		parameterName := func(v *types.Var) string {
			if v.Anonymous() || v.Name() == "" {
				return c.newVariable("param")
			}
			return c.newVariable(v.Name())
		}
		makeParametersList := func() []string {
			params := sel.Obj().Type().(*types.Signature).Params()
			names := make([]string, params.Len())
			for i := 0; i < params.Len(); i++ {
				names[i] = parameterName(params.At(i))
			}
			return names
		}

		switch sel.Kind() {
		case types.FieldVal:
			fields, jsTag := c.translateSelection(sel)
			if jsTag != "" {
				if _, ok := sel.Type().(*types.Signature); ok {
					return c.formatExpr("go$internalize(%1e.%2s.%3s, %4s, %1e.%2s)", e.X, strings.Join(fields, "."), jsTag, c.typeName(sel.Type()))
				}
				return c.internalize(c.formatExpr("%e.%s.%s", e.X, strings.Join(fields, "."), jsTag), sel.Type())
			}
			return c.formatExpr("%e.%s", e.X, strings.Join(fields, "."))
		case types.MethodVal:
			if !sel.Obj().Exported() {
				c.p.dependencies[sel.Obj()] = true
			}
			parameters := makeParametersList()
			target := c.translateExpr(e.X)
			if isWrapped(sel.Recv()) {
				target = c.formatParenExpr("new %s(%s)", c.typeName(sel.Recv()), target)
			}
			recv := c.newVariable("_recv")
			return c.formatExpr("(%s = %s, function(%s) { return %s.%s(%s); })", recv, target, strings.Join(parameters, ", "), recv, e.Sel.Name, strings.Join(parameters, ", "))
		case types.MethodExpr:
			if !sel.Obj().Exported() {
				c.p.dependencies[sel.Obj()] = true
			}
			recv := "recv"
			if isWrapped(sel.Recv()) {
				recv = fmt.Sprintf("(new %s(recv))", c.typeName(sel.Recv()))
			}
			parameters := makeParametersList()
			return c.formatExpr("(function(%s) { return %s.%s(%s); })", strings.Join(append([]string{"recv"}, parameters...), ", "), recv, sel.Obj().(*types.Func).Name(), strings.Join(parameters, ", "))
		case types.PackageObj:
			if isJsPackage(sel.Obj().Pkg()) {
				switch sel.Obj().Name() {
				case "Global":
					return c.formatExpr("go$global")
				case "This":
					if c.flattened {
						return c.formatExpr("go$this")
					}
					return c.formatExpr("this")
				case "Arguments":
					args := "arguments"
					if c.flattened {
						args = "go$args"
					}

					return c.formatExpr(`new (go$sliceType(%s.Object))(go$global.Array.prototype.slice.call(%s))`, c.p.pkgVars["github.com/gopherjs/gopherjs/js"], args)
				default:
					panic("Invalid js package object: " + sel.Obj().Name())
				}
			}
			return c.formatExpr("%s", c.objectName(sel.Obj()))
		}
		panic("")

	case *ast.CallExpr:
		plainFun := e.Fun
		for {
			if p, isParen := plainFun.(*ast.ParenExpr); isParen {
				plainFun = p.X
				continue
			}
			break
		}

		var isType func(ast.Expr) bool
		isType = func(expr ast.Expr) bool {
			switch e := expr.(type) {
			case *ast.ArrayType, *ast.ChanType, *ast.FuncType, *ast.InterfaceType, *ast.MapType, *ast.StructType:
				return true
			case *ast.StarExpr:
				return isType(e.X)
			case *ast.Ident:
				_, ok := c.p.info.Uses[e].(*types.TypeName)
				return ok
			case *ast.SelectorExpr:
				_, ok := c.p.info.Uses[e.Sel].(*types.TypeName)
				return ok
			case *ast.ParenExpr:
				return isType(e.X)
			default:
				return false
			}
		}

		if isType(plainFun) {
			return c.formatExpr("%s", c.translateConversion(e.Args[0], c.p.info.Types[plainFun].Type))
		}

		var fun *expression
		switch f := plainFun.(type) {
		case *ast.Ident:
			if o, ok := c.p.info.Uses[f].(*types.Builtin); ok {
				switch o.Name() {
				case "new":
					t := c.p.info.Types[e].Type.(*types.Pointer)
					if c.p.pkg.Path() == "syscall" && types.Identical(t.Elem().Underlying(), types.Typ[types.Uintptr]) {
						return c.formatExpr("new Uint8Array(8)")
					}
					switch t.Elem().Underlying().(type) {
					case *types.Struct, *types.Array:
						return c.formatExpr("%s", c.zeroValue(t.Elem()))
					default:
						return c.formatExpr("go$newDataPointer(%s, %s)", c.zeroValue(t.Elem()), c.typeName(t))
					}
				case "make":
					switch argType := c.p.info.Types[e.Args[0]].Type.Underlying().(type) {
					case *types.Slice:
						t := c.typeName(c.p.info.Types[e.Args[0]].Type)
						if len(e.Args) == 3 {
							return c.formatExpr("%s.make(%f, %f, function() { return %s; })", t, e.Args[1], e.Args[2], c.zeroValue(argType.Elem()))
						}
						return c.formatExpr("%s.make(%f, 0, function() { return %s; })", t, e.Args[1], c.zeroValue(argType.Elem()))
					case *types.Map:
						return c.formatExpr("new Go$Map()")
					case *types.Chan:
						return c.formatExpr("new %s()", c.typeName(c.p.info.Types[e.Args[0]].Type))
					default:
						panic(fmt.Sprintf("Unhandled make type: %T\n", argType))
					}
				case "len":
					arg := c.translateExpr(e.Args[0])
					switch argType := c.p.info.Types[e.Args[0]].Type.Underlying().(type) {
					case *types.Basic, *types.Slice:
						return c.formatExpr("%s.length", arg)
					case *types.Pointer:
						return c.formatExpr("(%s, %d)", arg, argType.Elem().(*types.Array).Len())
					case *types.Map:
						return c.formatExpr("go$keys(%s).length", arg)
					case *types.Chan:
						return c.formatExpr("0")
					// length of array is constant
					default:
						panic(fmt.Sprintf("Unhandled len type: %T\n", argType))
					}
				case "cap":
					arg := c.translateExpr(e.Args[0])
					switch argType := c.p.info.Types[e.Args[0]].Type.Underlying().(type) {
					case *types.Slice:
						return c.formatExpr("%s.capacity", arg)
					case *types.Pointer:
						return c.formatExpr("(%s, %d)", arg, argType.Elem().(*types.Array).Len())
					case *types.Chan:
						return c.formatExpr("0")
					// capacity of array is constant
					default:
						panic(fmt.Sprintf("Unhandled cap type: %T\n", argType))
					}
				case "panic":
					return c.formatExpr("throw go$panic(%s)", c.translateImplicitConversion(e.Args[0], types.NewInterface(nil, nil)))
				case "append":
					if len(e.Args) == 1 {
						return c.translateExpr(e.Args[0])
					}
					if e.Ellipsis.IsValid() {
						return c.formatExpr("go$appendSlice(%e, %s)", e.Args[0], c.translateConversionToSlice(e.Args[1], exprType))
					}
					sliceType := exprType.Underlying().(*types.Slice)
					return c.formatExpr("go$append(%e, %s)", e.Args[0], strings.Join(c.translateExprSlice(e.Args[1:], sliceType.Elem()), ", "))
				case "delete":
					return c.formatExpr(`delete %e[%s]`, e.Args[0], c.makeKey(e.Args[1], c.p.info.Types[e.Args[0]].Type.Underlying().(*types.Map).Key()))
				case "copy":
					if basic, isBasic := c.p.info.Types[e.Args[1]].Type.Underlying().(*types.Basic); isBasic && basic.Info()&types.IsString != 0 {
						return c.formatExpr("go$copyString(%e, %e)", e.Args[0], e.Args[1])
					}
					return c.formatExpr("go$copySlice(%e, %e)", e.Args[0], e.Args[1])
				case "print", "println":
					return c.formatExpr("console.log(%s)", strings.Join(c.translateExprSlice(e.Args, nil), ", "))
				case "complex":
					return c.formatExpr("new %s(%e, %e)", c.typeName(c.p.info.Types[e].Type), e.Args[0], e.Args[1])
				case "real":
					return c.formatExpr("%e.real", e.Args[0])
				case "imag":
					return c.formatExpr("%e.imag", e.Args[0])
				case "recover":
					return c.formatExpr("go$recover()")
				case "close":
					return c.formatExpr(`go$notSupported("close")`)
				default:
					panic(fmt.Sprintf("Unhandled builtin: %s\n", o.Name()))
				}
			}
			fun = c.translateExpr(plainFun)

		case *ast.SelectorExpr:
			sel := c.p.info.Selections[f]
			o := sel.Obj()

			externalizeExpr := func(e ast.Expr) string {
				t := c.p.info.Types[e].Type
				if types.Identical(t, types.Typ[types.UntypedNil]) {
					return "null"
				}
				return c.externalize(c.translateExpr(e).String(), t)
			}
			externalizeArgs := func(args []ast.Expr) string {
				s := make([]string, len(args))
				for i, arg := range args {
					s[i] = externalizeExpr(arg)
				}
				return strings.Join(s, ", ")
			}

			switch sel.Kind() {
			case types.MethodVal:
				if !sel.Obj().Exported() {
					c.p.dependencies[sel.Obj()] = true
				}

				methodName := o.Name()
				if reservedKeywords[methodName] {
					methodName += "$"
				}

				fun = c.translateExpr(f.X)
				t := sel.Recv()
				for _, index := range sel.Index()[:len(sel.Index())-1] {
					if ptr, isPtr := t.(*types.Pointer); isPtr {
						t = ptr.Elem()
					}
					s := t.Underlying().(*types.Struct)
					fun = c.formatExpr("%s.%s", fun, fieldName(s, index))
					t = s.Field(index).Type()
				}

				if isJsPackage(o.Pkg()) {
					globalRef := func(id string) string {
						if fun.String() == "go$global" && len(id) > 3 && strings.EqualFold(id[:3], "go$") {
							return id
						}
						return fun.String() + "." + id
					}
					switch o.Name() {
					case "Get":
						if id, ok := c.identifierConstant(e.Args[0]); ok {
							return c.formatExpr("%s", globalRef(id))
						}
						return c.formatExpr("%s[go$externalize(%e, Go$String)]", fun, e.Args[0])
					case "Set":
						if id, ok := c.identifierConstant(e.Args[0]); ok {
							return c.formatExpr("%s = %s", globalRef(id), externalizeExpr(e.Args[1]))
						}
						return c.formatExpr("%s[go$externalize(%e, Go$String)] = %s", fun, e.Args[0], externalizeExpr(e.Args[1]))
					case "Delete":
						return c.formatExpr("delete %s[go$externalize(%e, Go$String)]", fun, e.Args[0])
					case "Length":
						return c.formatExpr("go$parseInt(%s.length)", fun)
					case "Index":
						return c.formatExpr("%s[%e]", fun, e.Args[0])
					case "SetIndex":
						return c.formatExpr("%s[%e] = %s", fun, e.Args[0], externalizeExpr(e.Args[1]))
					case "Call":
						if id, ok := c.identifierConstant(e.Args[0]); ok {
							if e.Ellipsis.IsValid() {
								objVar := c.newVariable("obj")
								return c.formatExpr("(%s = %s, %s.%s.apply(%s, %s))", objVar, fun, objVar, id, objVar, externalizeExpr(e.Args[1]))
							}
							return c.formatExpr("%s(%s)", globalRef(id), externalizeArgs(e.Args[1:]))
						}
						if e.Ellipsis.IsValid() {
							objVar := c.newVariable("obj")
							return c.formatExpr("(%s = %s, %s[go$externalize(%e, Go$String)].apply(%s, %s))", objVar, fun, objVar, e.Args[0], objVar, externalizeExpr(e.Args[1]))
						}
						return c.formatExpr("%s[go$externalize(%e, Go$String)](%s)", fun, e.Args[0], externalizeArgs(e.Args[1:]))
					case "Invoke":
						if e.Ellipsis.IsValid() {
							return c.formatExpr("%s.apply(undefined, %s)", fun, externalizeExpr(e.Args[0]))
						}
						return c.formatExpr("%s(%s)", fun, externalizeArgs(e.Args))
					case "New":
						if e.Ellipsis.IsValid() {
							return c.formatExpr("new (go$global.Function.prototype.bind.apply(%s, [undefined].concat(%s)))", fun, externalizeExpr(e.Args[0]))
						}
						return c.formatExpr("new (%s)(%s)", fun, externalizeArgs(e.Args))
					case "Bool":
						return c.internalize(fun, types.Typ[types.Bool])
					case "Str":
						return c.internalize(fun, types.Typ[types.String])
					case "Int":
						return c.internalize(fun, types.Typ[types.Int])
					case "Int64":
						return c.internalize(fun, types.Typ[types.Int64])
					case "Uint64":
						return c.internalize(fun, types.Typ[types.Uint64])
					case "Float":
						return c.internalize(fun, types.Typ[types.Float64])
					case "Interface":
						return c.internalize(fun, types.NewInterface(nil, nil))
					case "Unsafe":
						return fun
					case "IsUndefined":
						return c.formatParenExpr("%s === undefined", fun)
					case "IsNull":
						return c.formatParenExpr("%s === null", fun)
					default:
						panic("Invalid js package object: " + o.Name())
					}
				}

				methodsRecvType := o.Type().(*types.Signature).Recv().Type()
				_, pointerExpected := methodsRecvType.(*types.Pointer)
				_, isPointer := t.Underlying().(*types.Pointer)
				_, isStruct := t.Underlying().(*types.Struct)
				_, isArray := t.Underlying().(*types.Array)
				if pointerExpected && !isPointer && !isStruct && !isArray {
					vVar := c.newVariable("v")
					fun = c.formatExpr("(new %s(function() { return %s; }, function(%s) { %s = %s; })).%s", c.typeName(methodsRecvType), fun, vVar, fun, vVar, methodName)
					break
				}

				if isWrapped(t) {
					fun = c.formatExpr("(new %s(%s)).%s", c.typeName(t), fun, methodName)
					break
				}
				fun = c.formatExpr("%s.%s", fun, methodName)

			case types.PackageObj:
				if isJsPackage(o.Pkg()) && o.Name() == "InternalObject" {
					return c.translateExpr(e.Args[0])
				}
				fun = c.translateExpr(f)

			case types.FieldVal:
				fields, jsTag := c.translateSelection(sel)
				if jsTag != "" {
					sig := sel.Type().(*types.Signature)
					return c.internalize(c.formatExpr("%e.%s.%s(%s)", f.X, strings.Join(fields, "."), jsTag, externalizeArgs(e.Args)), sig.Results().At(0).Type())
				}
				fun = c.formatExpr("%e.%s", f.X, strings.Join(fields, "."))

			case types.MethodExpr:
				fun = c.translateExpr(f)

			default:
				panic("")
			}
		default:
			fun = c.translateExpr(plainFun)
		}

		sig := c.p.info.Types[plainFun].Type.Underlying().(*types.Signature)
		if len(e.Args) == 1 {
			if tuple, isTuple := c.p.info.Types[e.Args[0]].Type.(*types.Tuple); isTuple {
				tupleVar := c.newVariable("_tuple")
				args := make([]ast.Expr, tuple.Len())
				for i := range args {
					args[i] = c.newIdent(c.formatExpr("%s[%d]", tupleVar, i).String(), tuple.At(i).Type())
				}
				return c.formatExpr("(%s = %e, %s(%s))", tupleVar, e.Args[0], fun, strings.Join(c.translateArgs(sig, args, false), ", "))
			}
		}
		return c.formatExpr("%s(%s)", fun, strings.Join(c.translateArgs(sig, e.Args, e.Ellipsis.IsValid()), ", "))

	case *ast.StarExpr:
		if c1, isCall := e.X.(*ast.CallExpr); isCall && len(c1.Args) == 1 {
			if c2, isCall := c1.Args[0].(*ast.CallExpr); isCall && len(c2.Args) == 1 && types.Identical(c.p.info.Types[c2.Fun].Type, types.Typ[types.UnsafePointer]) {
				if unary, isUnary := c2.Args[0].(*ast.UnaryExpr); isUnary && unary.Op == token.AND {
					return c.translateExpr(unary.X) // unsafe conversion
				}
			}
		}
		switch exprType.Underlying().(type) {
		case *types.Struct, *types.Array:
			return c.translateExpr(e.X)
		}
		return c.formatExpr("%e.go$get()", e.X)

	case *ast.TypeAssertExpr:
		if e.Type == nil {
			return c.translateExpr(e.X)
		}
		t := c.p.info.Types[e.Type].Type
		check := "%1e !== null && " + c.typeCheck("%1e.constructor", t)
		valueSuffix := ""
		if _, isInterface := t.Underlying().(*types.Interface); !isInterface {
			valueSuffix = ".go$val"
		}
		if _, isTuple := exprType.(*types.Tuple); isTuple {
			return c.formatExpr("("+check+" ? [%1e%2s, true] : [%3s, false])", e.X, valueSuffix, c.zeroValue(c.p.info.Types[e.Type].Type))
		}
		return c.formatExpr("("+check+" ? %1e%2s : go$typeAssertionFailed(%1e, %3s))", e.X, valueSuffix, c.typeName(t))

	case *ast.Ident:
		if e.Name == "_" {
			panic("Tried to translate underscore identifier.")
		}
		switch o := c.p.info.Uses[e].(type) {
		case *types.PkgName:
			return c.formatExpr("%s", c.p.pkgVars[o.Pkg().Path()])
		case *types.Var, *types.Const:
			return c.formatExpr("%s", c.objectName(o))
		case *types.Func:
			return c.formatExpr("%s", c.objectName(o))
		case *types.TypeName:
			return c.formatExpr("%s", c.typeName(o.Type()))
		case *types.Nil:
			return c.formatExpr("%s", c.zeroValue(c.p.info.Types[e].Type))
		default:
			panic(fmt.Sprintf("Unhandled object: %T\n", o))
		}

	case *This:
		this := "this"
		if c.flattened {
			this = "go$this"
		}
		if isWrapped(c.p.info.Types[e].Type) {
			this += ".go$val"
		}
		return c.formatExpr(this)

	case nil:
		return c.formatExpr("")

	default:
		panic(fmt.Sprintf("Unhandled expression: %T\n", e))

	}
}
Esempio n. 16
0
// builtin typechecks a call to a built-in and returns the result via x.
// If the call has type errors, the returned x is marked as invalid.
//
func (check *checker) builtin(x *operand, call *ast.CallExpr, id builtinId) {
	args := call.Args

	// declare before goto's
	var arg0 ast.Expr // first argument, if present

	// check argument count
	n := len(args)
	msg := ""
	bin := predeclaredFuncs[id]
	if n < bin.nargs {
		msg = "not enough"
	} else if !bin.variadic && n > bin.nargs {
		msg = "too many"
	}
	if msg != "" {
		check.invalidOp(call.Pos(), msg+" arguments for %s (expected %d, found %d)", call, bin.nargs, n)
		goto Error
	}

	// common case: evaluate first argument if present;
	// if it is an expression, x has the expression value
	if n > 0 {
		arg0 = args[0]
		switch id {
		case _Make, _New, _Print, _Println, _Offsetof, _Trace:
			// respective cases below do the work
		default:
			// argument must be an expression
			check.expr(x, arg0)
			if x.mode == invalid {
				goto Error
			}
		}
	}

	switch id {
	case _Append:
		if _, ok := x.typ.Underlying().(*Slice); !ok {
			check.invalidArg(x.pos(), "%s is not a typed slice", x)
			goto Error
		}
		resultTyp := x.typ
		for _, arg := range args[1:] {
			check.expr(x, arg)
			if x.mode == invalid {
				goto Error
			}
			// TODO(gri) check assignability
		}
		x.mode = value
		x.typ = resultTyp

	case _Cap, _Len:
		mode := invalid
		var val exact.Value
		switch typ := implicitArrayDeref(x.typ.Underlying()).(type) {
		case *Basic:
			if isString(typ) && id == _Len {
				if x.mode == constant {
					mode = constant
					val = exact.MakeInt64(int64(len(exact.StringVal(x.val))))
				} else {
					mode = value
				}
			}

		case *Array:
			mode = value
			// spec: "The expressions len(s) and cap(s) are constants
			// if the type of s is an array or pointer to an array and
			// the expression s does not contain channel receives or
			// function calls; in this case s is not evaluated."
			if !check.containsCallsOrReceives(arg0) {
				mode = constant
				val = exact.MakeInt64(typ.len)
			}

		case *Slice, *Chan:
			mode = value

		case *Map:
			if id == _Len {
				mode = value
			}
		}

		if mode == invalid {
			check.invalidArg(x.pos(), "%s for %s", x, bin.name)
			goto Error
		}
		x.mode = mode
		x.typ = Typ[Int]
		x.val = val

	case _Close:
		ch, ok := x.typ.Underlying().(*Chan)
		if !ok {
			check.invalidArg(x.pos(), "%s is not a channel", x)
			goto Error
		}
		if ch.dir&ast.SEND == 0 {
			check.invalidArg(x.pos(), "%s must not be a receive-only channel", x)
			goto Error
		}
		x.mode = novalue

	case _Complex:
		if !check.complexArg(x) {
			goto Error
		}

		var y operand
		check.expr(&y, args[1])
		if y.mode == invalid {
			goto Error
		}
		if !check.complexArg(&y) {
			goto Error
		}

		check.convertUntyped(x, y.typ)
		if x.mode == invalid {
			goto Error
		}
		check.convertUntyped(&y, x.typ)
		if y.mode == invalid {
			goto Error
		}

		if !IsIdentical(x.typ, y.typ) {
			check.invalidArg(x.pos(), "mismatched types %s and %s", x.typ, y.typ)
			goto Error
		}

		typ := x.typ.Underlying().(*Basic)
		if x.mode == constant && y.mode == constant {
			x.val = exact.BinaryOp(x.val, token.ADD, exact.MakeImag(y.val))
		} else {
			x.mode = value
		}

		switch typ.kind {
		case Float32:
			x.typ = Typ[Complex64]
		case Float64:
			x.typ = Typ[Complex128]
		case UntypedInt, UntypedRune, UntypedFloat:
			if x.mode == constant {
				typ = defaultType(typ).(*Basic)
				x.typ = Typ[UntypedComplex]
			} else {
				// untyped but not constant; probably because one
				// operand is a non-constant shift of untyped lhs
				typ = Typ[Float64]
				x.typ = Typ[Complex128]
			}
		default:
			check.invalidArg(x.pos(), "float32 or float64 arguments expected")
			goto Error
		}

		if x.mode != constant {
			// The arguments have now their final types, which at run-
			// time will be materialized. Update the expression trees.
			// If the current types are untyped, the materialized type
			// is the respective default type.
			// (If the result is constant, the arguments are never
			// materialized and there is nothing to do.)
			check.updateExprType(args[0], typ, true)
			check.updateExprType(args[1], typ, true)
		}

	case _Copy:
		var y operand
		check.expr(&y, args[1])
		if y.mode == invalid {
			goto Error
		}

		var dst, src Type
		if t, ok := x.typ.Underlying().(*Slice); ok {
			dst = t.elt
		}
		switch t := y.typ.Underlying().(type) {
		case *Basic:
			if isString(y.typ) {
				src = Typ[Byte]
			}
		case *Slice:
			src = t.elt
		}

		if dst == nil || src == nil {
			check.invalidArg(x.pos(), "copy expects slice arguments; found %s and %s", x, &y)
			goto Error
		}

		if !IsIdentical(dst, src) {
			check.invalidArg(x.pos(), "arguments to copy %s and %s have different element types %s and %s", x, &y, dst, src)
			goto Error
		}

		x.mode = value
		x.typ = Typ[Int]

	case _Delete:
		m, ok := x.typ.Underlying().(*Map)
		if !ok {
			check.invalidArg(x.pos(), "%s is not a map", x)
			goto Error
		}
		check.expr(x, args[1])
		if x.mode == invalid {
			goto Error
		}
		if !x.isAssignableTo(check.conf, m.key) {
			check.invalidArg(x.pos(), "%s is not assignable to %s", x, m.key)
			goto Error
		}
		x.mode = novalue

	case _Imag, _Real:
		if !isComplex(x.typ) {
			check.invalidArg(x.pos(), "%s must be a complex number", x)
			goto Error
		}
		if x.mode == constant {
			if id == _Real {
				x.val = exact.Real(x.val)
			} else {
				x.val = exact.Imag(x.val)
			}
		} else {
			x.mode = value
		}
		k := Invalid
		switch x.typ.Underlying().(*Basic).kind {
		case Complex64:
			k = Float32
		case Complex128:
			k = Float64
		case UntypedComplex:
			k = UntypedFloat
		default:
			unreachable()
		}
		x.typ = Typ[k]

	case _Make:
		resultTyp := check.typ(arg0, nil, false)
		if resultTyp == Typ[Invalid] {
			goto Error
		}
		var min int // minimum number of arguments
		switch resultTyp.Underlying().(type) {
		case *Slice:
			min = 2
		case *Map, *Chan:
			min = 1
		default:
			check.invalidArg(arg0.Pos(), "cannot make %s; type must be slice, map, or channel", arg0)
			goto Error
		}
		if n := len(args); n < min || min+1 < n {
			check.errorf(call.Pos(), "%s expects %d or %d arguments; found %d", call, min, min+1, n)
			goto Error
		}
		var sizes []int64 // constant integer arguments, if any
		for _, arg := range args[1:] {
			if s, ok := check.index(arg, -1); ok && s >= 0 {
				sizes = append(sizes, s)
			}
		}
		if len(sizes) == 2 && sizes[0] > sizes[1] {
			check.invalidArg(args[1].Pos(), "length and capacity swapped")
			// safe to continue
		}
		x.mode = variable
		x.typ = resultTyp

	case _New:
		resultTyp := check.typ(arg0, nil, false)
		if resultTyp == Typ[Invalid] {
			goto Error
		}
		x.mode = variable
		x.typ = &Pointer{base: resultTyp}

	case _Panic:
		x.mode = novalue

	case _Print, _Println:
		for _, arg := range args {
			check.expr(x, arg)
			if x.mode == invalid {
				goto Error
			}
		}
		x.mode = novalue

	case _Recover:
		x.mode = value
		x.typ = new(Interface)

	case _Alignof:
		x.mode = constant
		x.val = exact.MakeInt64(check.conf.alignof(x.typ))
		x.typ = Typ[Uintptr]

	case _Offsetof:
		arg, ok := unparen(arg0).(*ast.SelectorExpr)
		if !ok {
			check.invalidArg(arg0.Pos(), "%s is not a selector expression", arg0)
			goto Error
		}
		check.expr(x, arg.X)
		if x.mode == invalid {
			goto Error
		}
		base := derefStructPtr(x.typ)
		sel := arg.Sel.Name
		obj, index, indirect := LookupFieldOrMethod(base, check.pkg, arg.Sel.Name)
		switch obj.(type) {
		case nil:
			check.invalidArg(x.pos(), "%s has no single field %s", base, sel)
			goto Error
		case *Func:
			check.invalidArg(arg0.Pos(), "%s is a method value", arg0)
			goto Error
		}
		if indirect {
			check.invalidArg(x.pos(), "field %s is embedded via a pointer in %s", sel, base)
			goto Error
		}

		// TODO(gri) Should we pass x.typ instead of base (and indirect report if derefStructPtr indirected)?
		check.recordSelection(arg, FieldVal, base, obj, index, false)

		offs := check.conf.offsetof(base, index)
		x.mode = constant
		x.val = exact.MakeInt64(offs)
		x.typ = Typ[Uintptr]

	case _Sizeof:
		x.mode = constant
		x.val = exact.MakeInt64(check.conf.sizeof(x.typ))
		x.typ = Typ[Uintptr]

	case _Assert:
		// assert(pred) causes a typechecker error if pred is false.
		// The result of assert is the value of pred if there is no error.
		// Note: assert is only available in self-test mode.
		if x.mode != constant || !isBoolean(x.typ) {
			check.invalidArg(x.pos(), "%s is not a boolean constant", x)
			goto Error
		}
		if x.val.Kind() != exact.Bool {
			check.errorf(x.pos(), "internal error: value of %s should be a boolean constant", x)
			goto Error
		}
		if !exact.BoolVal(x.val) {
			check.errorf(call.Pos(), "%s failed", call)
			// compile-time assertion failure - safe to continue
		}

	case _Trace:
		// trace(x, y, z, ...) dumps the positions, expressions, and
		// values of its arguments. The result of trace is the value
		// of the first argument.
		// Note: trace is only available in self-test mode.
		if len(args) == 0 {
			check.dump("%s: trace() without arguments", call.Pos())
			x.mode = novalue
			x.expr = call
			return
		}
		var t operand
		x1 := x
		for _, arg := range args {
			check.rawExpr(x1, arg, nil) // permit trace for types, e.g.: new(trace(T))
			check.dump("%s: %s", x1.pos(), x1)
			x1 = &t // use incoming x only for first argument
		}

	default:
		unreachable()
	}

	x.expr = call
	return

Error:
	x.mode = invalid
	x.expr = call
}
Esempio n. 17
0
func (c *funcContext) translateExpr(expr ast.Expr) *expression {
	exprType := c.p.info.Types[expr].Type
	if value := c.p.info.Types[expr].Value; value != nil {
		basic := types.Typ[types.String]
		if value.Kind() != exact.String { // workaround for bug in go/types
			basic = exprType.Underlying().(*types.Basic)
		}
		switch {
		case basic.Info()&types.IsBoolean != 0:
			return c.formatExpr("%s", strconv.FormatBool(exact.BoolVal(value)))
		case basic.Info()&types.IsInteger != 0:
			if is64Bit(basic) {
				d, _ := exact.Uint64Val(value)
				if basic.Kind() == types.Int64 {
					return c.formatExpr("new %s(%s, %s)", c.typeName(exprType), strconv.FormatInt(int64(d)>>32, 10), strconv.FormatUint(d&(1<<32-1), 10))
				}
				return c.formatExpr("new %s(%s, %s)", c.typeName(exprType), strconv.FormatUint(d>>32, 10), strconv.FormatUint(d&(1<<32-1), 10))
			}
			d, _ := exact.Int64Val(value)
			return c.formatExpr("%s", strconv.FormatInt(d, 10))
		case basic.Info()&types.IsFloat != 0:
			f, _ := exact.Float64Val(value)
			return c.formatExpr("%s", strconv.FormatFloat(f, 'g', -1, 64))
		case basic.Info()&types.IsComplex != 0:
			r, _ := exact.Float64Val(exact.Real(value))
			i, _ := exact.Float64Val(exact.Imag(value))
			if basic.Kind() == types.UntypedComplex {
				exprType = types.Typ[types.Complex128]
			}
			return c.formatExpr("new %s(%s, %s)", c.typeName(exprType), strconv.FormatFloat(r, 'g', -1, 64), strconv.FormatFloat(i, 'g', -1, 64))
		case basic.Info()&types.IsString != 0:
			return c.formatExpr("%s", encodeString(exact.StringVal(value)))
		default:
			panic("Unhandled constant type: " + basic.String())
		}
	}

	switch e := expr.(type) {
	case *ast.CompositeLit:
		if ptrType, isPointer := exprType.(*types.Pointer); isPointer {
			exprType = ptrType.Elem()
		}

		collectIndexedElements := func(elementType types.Type) []string {
			elements := make([]string, 0)
			i := 0
			zero := c.zeroValue(elementType)
			for _, element := range e.Elts {
				if kve, isKve := element.(*ast.KeyValueExpr); isKve {
					key, _ := exact.Int64Val(c.p.info.Types[kve.Key].Value)
					i = int(key)
					element = kve.Value
				}
				for len(elements) <= i {
					elements = append(elements, zero)
				}
				elements[i] = c.translateImplicitConversionWithCloning(element, elementType).String()
				i++
			}
			return elements
		}

		switch t := exprType.Underlying().(type) {
		case *types.Array:
			elements := collectIndexedElements(t.Elem())
			if len(elements) == 0 {
				return c.formatExpr("%s", c.zeroValue(t))
			}
			zero := c.zeroValue(t.Elem())
			for len(elements) < int(t.Len()) {
				elements = append(elements, zero)
			}
			return c.formatExpr(`$toNativeArray("%s", [%s])`, typeKind(t.Elem()), strings.Join(elements, ", "))
		case *types.Slice:
			return c.formatExpr("new %s([%s])", c.typeName(exprType), strings.Join(collectIndexedElements(t.Elem()), ", "))
		case *types.Map:
			mapVar := c.newVariable("_map")
			keyVar := c.newVariable("_key")
			assignments := ""
			for _, element := range e.Elts {
				kve := element.(*ast.KeyValueExpr)
				assignments += c.formatExpr(`%s = %s, %s[%s] = { k: %s, v: %s }, `, keyVar, c.translateImplicitConversion(kve.Key, t.Key()), mapVar, c.makeKey(c.newIdent(keyVar, t.Key()), t.Key()), keyVar, c.translateImplicitConversion(kve.Value, t.Elem())).String()
			}
			return c.formatExpr("(%s = new $Map(), %s%s)", mapVar, assignments, mapVar)
		case *types.Struct:
			elements := make([]string, t.NumFields())
			isKeyValue := true
			if len(e.Elts) != 0 {
				_, isKeyValue = e.Elts[0].(*ast.KeyValueExpr)
			}
			if !isKeyValue {
				for i, element := range e.Elts {
					elements[i] = c.translateImplicitConversion(element, t.Field(i).Type()).String()
				}
			}
			if isKeyValue {
				for i := range elements {
					elements[i] = c.zeroValue(t.Field(i).Type())
				}
				for _, element := range e.Elts {
					kve := element.(*ast.KeyValueExpr)
					for j := range elements {
						if kve.Key.(*ast.Ident).Name == t.Field(j).Name() {
							elements[j] = c.translateImplicitConversion(kve.Value, t.Field(j).Type()).String()
							break
						}
					}
				}
			}
			return c.formatExpr("new %s.Ptr(%s)", c.typeName(exprType), strings.Join(elements, ", "))
		default:
			panic(fmt.Sprintf("Unhandled CompositeLit type: %T\n", t))
		}

	case *ast.FuncLit:
		innerContext := c.p.analyzeFunction(exprType.(*types.Signature), e.Body)
		params, body := innerContext.translateFunction(e.Type, e.Body.List, c.allVars)
		if len(c.p.escapingVars) != 0 {
			names := make([]string, 0, len(c.p.escapingVars))
			for obj := range c.p.escapingVars {
				names = append(names, c.p.objectVars[obj])
			}
			list := strings.Join(names, ", ")
			return c.formatExpr("(function(%s) { return function(%s) {\n%s%s}; })(%s)", list, strings.Join(params, ", "), string(body), strings.Repeat("\t", c.p.indentation), list)
		}
		return c.formatExpr("(function(%s) {\n%s%s})", strings.Join(params, ", "), string(body), strings.Repeat("\t", c.p.indentation))

	case *ast.UnaryExpr:
		t := c.p.info.Types[e.X].Type
		switch e.Op {
		case token.AND:
			switch t.Underlying().(type) {
			case *types.Struct, *types.Array:
				return c.translateExpr(e.X)
			}

			switch x := removeParens(e.X).(type) {
			case *ast.CompositeLit:
				return c.formatExpr("$newDataPointer(%e, %s)", x, c.typeName(c.p.info.Types[e].Type))
			case *ast.Ident:
				if obj := c.p.info.Uses[x]; c.p.escapingVars[obj] {
					return c.formatExpr("new %s(function() { return this.$target[0]; }, function($v) { this.$target[0] = $v; }, %s)", c.typeName(exprType), c.p.objectVars[obj])
				}
				return c.formatExpr("new %s(function() { return %e; }, function($v) { %s })", c.typeName(exprType), x, c.translateAssign(x, "$v", exprType, false))
			case *ast.SelectorExpr:
				newSel := &ast.SelectorExpr{X: c.newIdent("this.$target", c.p.info.Types[x.X].Type), Sel: x.Sel}
				c.p.info.Selections[newSel] = c.p.info.Selections[x]
				return c.formatExpr("new %s(function() { return %e; }, function($v) { %s }, %e)", c.typeName(exprType), newSel, c.translateAssign(newSel, "$v", exprType, false), x.X)
			case *ast.IndexExpr:
				newIndex := &ast.IndexExpr{X: c.newIdent("this.$target", c.p.info.Types[x.X].Type), Index: x.Index}
				return c.formatExpr("new %s(function() { return %e; }, function($v) { %s }, %e)", c.typeName(exprType), newIndex, c.translateAssign(newIndex, "$v", exprType, false), x.X)
			default:
				panic(fmt.Sprintf("Unhandled: %T\n", x))
			}

		case token.ARROW:
			call := &ast.CallExpr{
				Fun:  c.newIdent("$recv", types.NewSignature(nil, nil, types.NewTuple(types.NewVar(0, nil, "", t)), types.NewTuple(types.NewVar(0, nil, "", exprType), types.NewVar(0, nil, "", types.Typ[types.Bool])), false)),
				Args: []ast.Expr{e.X},
			}
			c.blocking[call] = true
			if _, isTuple := exprType.(*types.Tuple); isTuple {
				return c.formatExpr("%e", call)
			}
			return c.formatExpr("%e[0]", call)
		}

		basic := t.Underlying().(*types.Basic)
		switch e.Op {
		case token.ADD:
			return c.translateExpr(e.X)
		case token.SUB:
			switch {
			case is64Bit(basic):
				return c.formatExpr("new %1s(-%2h, -%2l)", c.typeName(t), e.X)
			case basic.Info()&types.IsComplex != 0:
				return c.formatExpr("new %1s(-%2r, -%2i)", c.typeName(t), e.X)
			case basic.Info()&types.IsUnsigned != 0:
				return c.fixNumber(c.formatExpr("-%e", e.X), basic)
			default:
				return c.formatExpr("-%e", e.X)
			}
		case token.XOR:
			if is64Bit(basic) {
				return c.formatExpr("new %1s(~%2h, ~%2l >>> 0)", c.typeName(t), e.X)
			}
			return c.fixNumber(c.formatExpr("~%e", e.X), basic)
		case token.NOT:
			x := c.translateExpr(e.X)
			if x.String() == "true" {
				return c.formatExpr("false")
			}
			if x.String() == "false" {
				return c.formatExpr("true")
			}
			return c.formatExpr("!%s", x)
		default:
			panic(e.Op)
		}

	case *ast.BinaryExpr:
		if e.Op == token.NEQ {
			return c.formatExpr("!(%s)", c.translateExpr(&ast.BinaryExpr{
				X:  e.X,
				Op: token.EQL,
				Y:  e.Y,
			}))
		}

		t := c.p.info.Types[e.X].Type
		t2 := c.p.info.Types[e.Y].Type
		_, isInterface := t2.Underlying().(*types.Interface)
		if isInterface {
			t = t2
		}

		if basic, isBasic := t.Underlying().(*types.Basic); isBasic && basic.Info()&types.IsNumeric != 0 {
			if is64Bit(basic) {
				switch e.Op {
				case token.MUL:
					return c.formatExpr("$mul64(%e, %e)", e.X, e.Y)
				case token.QUO:
					return c.formatExpr("$div64(%e, %e, false)", e.X, e.Y)
				case token.REM:
					return c.formatExpr("$div64(%e, %e, true)", e.X, e.Y)
				case token.SHL:
					return c.formatExpr("$shiftLeft64(%e, %f)", e.X, e.Y)
				case token.SHR:
					return c.formatExpr("$shiftRight%s(%e, %f)", toJavaScriptType(basic), e.X, e.Y)
				case token.EQL:
					return c.formatExpr("(%1h === %2h && %1l === %2l)", e.X, e.Y)
				case token.LSS:
					return c.formatExpr("(%1h < %2h || (%1h === %2h && %1l < %2l))", e.X, e.Y)
				case token.LEQ:
					return c.formatExpr("(%1h < %2h || (%1h === %2h && %1l <= %2l))", e.X, e.Y)
				case token.GTR:
					return c.formatExpr("(%1h > %2h || (%1h === %2h && %1l > %2l))", e.X, e.Y)
				case token.GEQ:
					return c.formatExpr("(%1h > %2h || (%1h === %2h && %1l >= %2l))", e.X, e.Y)
				case token.ADD, token.SUB:
					return c.formatExpr("new %3s(%1h %4t %2h, %1l %4t %2l)", e.X, e.Y, c.typeName(t), e.Op)
				case token.AND, token.OR, token.XOR:
					return c.formatExpr("new %3s(%1h %4t %2h, (%1l %4t %2l) >>> 0)", e.X, e.Y, c.typeName(t), e.Op)
				case token.AND_NOT:
					return c.formatExpr("new %3s(%1h &~ %2h, (%1l &~ %2l) >>> 0)", e.X, e.Y, c.typeName(t))
				default:
					panic(e.Op)
				}
			}

			if basic.Info()&types.IsComplex != 0 {
				switch e.Op {
				case token.EQL:
					if basic.Kind() == types.Complex64 {
						return c.formatExpr("($float32IsEqual(%1r, %2r) && $float32IsEqual(%1i, %2i))", e.X, e.Y)
					}
					return c.formatExpr("(%1r === %2r && %1i === %2i)", e.X, e.Y)
				case token.ADD, token.SUB:
					return c.formatExpr("new %3s(%1r %4t %2r, %1i %4t %2i)", e.X, e.Y, c.typeName(t), e.Op)
				case token.MUL:
					return c.formatExpr("new %3s(%1r * %2r - %1i * %2i, %1r * %2i + %1i * %2r)", e.X, e.Y, c.typeName(t))
				case token.QUO:
					return c.formatExpr("$divComplex(%e, %e)", e.X, e.Y)
				default:
					panic(e.Op)
				}
			}

			switch e.Op {
			case token.EQL:
				if basic.Kind() == types.Float32 {
					return c.formatParenExpr("$float32IsEqual(%e, %e)", e.X, e.Y)
				}
				return c.formatParenExpr("%e === %e", e.X, e.Y)
			case token.LSS, token.LEQ, token.GTR, token.GEQ:
				return c.formatExpr("%e %t %e", e.X, e.Op, e.Y)
			case token.ADD, token.SUB:
				if basic.Info()&types.IsInteger != 0 {
					return c.fixNumber(c.formatExpr("%e %t %e", e.X, e.Op, e.Y), basic)
				}
				return c.formatExpr("%e %t %e", e.X, e.Op, e.Y)
			case token.MUL:
				switch basic.Kind() {
				case types.Int32, types.Int:
					return c.formatParenExpr("(((%1e >>> 16 << 16) * %2e >> 0) + (%1e << 16 >>> 16) * %2e) >> 0", e.X, e.Y)
				case types.Uint32, types.Uint, types.Uintptr:
					return c.formatParenExpr("(((%1e >>> 16 << 16) * %2e >>> 0) + (%1e << 16 >>> 16) * %2e) >>> 0", e.X, e.Y)
				case types.Float32, types.Float64:
					return c.formatExpr("%e * %e", e.X, e.Y)
				default:
					return c.fixNumber(c.formatExpr("%e * %e", e.X, e.Y), basic)
				}
			case token.QUO:
				if basic.Info()&types.IsInteger != 0 {
					// cut off decimals
					shift := ">>"
					if basic.Info()&types.IsUnsigned != 0 {
						shift = ">>>"
					}
					return c.formatExpr(`(%1s = %2e / %3e, (%1s === %1s && %1s !== 1/0 && %1s !== -1/0) ? %1s %4s 0 : $throwRuntimeError("integer divide by zero"))`, c.newVariable("_q"), e.X, e.Y, shift)
				}
				return c.formatExpr("%e / %e", e.X, e.Y)
			case token.REM:
				return c.formatExpr(`(%1s = %2e %% %3e, %1s === %1s ? %1s : $throwRuntimeError("integer divide by zero"))`, c.newVariable("_r"), e.X, e.Y)
			case token.SHL, token.SHR:
				op := e.Op.String()
				if e.Op == token.SHR && basic.Info()&types.IsUnsigned != 0 {
					op = ">>>"
				}
				if c.p.info.Types[e.Y].Value != nil {
					return c.fixNumber(c.formatExpr("%e %s %e", e.X, op, e.Y), basic)
				}
				if e.Op == token.SHR && basic.Info()&types.IsUnsigned == 0 {
					return c.fixNumber(c.formatParenExpr("%e >> $min(%e, 31)", e.X, e.Y), basic)
				}
				y := c.newVariable("y")
				return c.fixNumber(c.formatExpr("(%s = %s, %s < 32 ? (%e %s %s) : 0)", y, c.translateImplicitConversion(e.Y, types.Typ[types.Uint]), y, e.X, op, y), basic)
			case token.AND, token.OR:
				if basic.Info()&types.IsUnsigned != 0 {
					return c.formatParenExpr("(%e %t %e) >>> 0", e.X, e.Op, e.Y)
				}
				return c.formatParenExpr("%e %t %e", e.X, e.Op, e.Y)
			case token.AND_NOT:
				return c.formatParenExpr("%e & ~%e", e.X, e.Y)
			case token.XOR:
				return c.fixNumber(c.formatParenExpr("%e ^ %e", e.X, e.Y), basic)
			default:
				panic(e.Op)
			}
		}

		switch e.Op {
		case token.ADD, token.LSS, token.LEQ, token.GTR, token.GEQ:
			return c.formatExpr("%e %t %e", e.X, e.Op, e.Y)
		case token.LAND:
			x := c.translateExpr(e.X)
			y := c.translateExpr(e.Y)
			if x.String() == "false" {
				return c.formatExpr("false")
			}
			return c.formatExpr("%s && %s", x, y)
		case token.LOR:
			x := c.translateExpr(e.X)
			y := c.translateExpr(e.Y)
			if x.String() == "true" {
				return c.formatExpr("true")
			}
			return c.formatExpr("%s || %s", x, y)
		case token.EQL:
			switch u := t.Underlying().(type) {
			case *types.Array, *types.Struct:
				return c.formatExpr("$equal(%e, %e, %s)", e.X, e.Y, c.typeName(t))
			case *types.Interface:
				if isJsObject(t) {
					return c.formatExpr("%s === %s", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
				}
				return c.formatExpr("$interfaceIsEqual(%s, %s)", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
			case *types.Pointer:
				xUnary, xIsUnary := e.X.(*ast.UnaryExpr)
				yUnary, yIsUnary := e.Y.(*ast.UnaryExpr)
				if xIsUnary && xUnary.Op == token.AND && yIsUnary && yUnary.Op == token.AND {
					xIndex, xIsIndex := xUnary.X.(*ast.IndexExpr)
					yIndex, yIsIndex := yUnary.X.(*ast.IndexExpr)
					if xIsIndex && yIsIndex {
						return c.formatExpr("$sliceIsEqual(%e, %f, %e, %f)", xIndex.X, xIndex.Index, yIndex.X, yIndex.Index)
					}
				}
				switch u.Elem().Underlying().(type) {
				case *types.Struct, *types.Interface:
					return c.formatExpr("%s === %s", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
				case *types.Array:
					return c.formatExpr("$equal(%s, %s, %s)", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t), c.typeName(u.Elem()))
				default:
					return c.formatExpr("$pointerIsEqual(%s, %s)", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
				}
			default:
				return c.formatExpr("%s === %s", c.translateImplicitConversion(e.X, t), c.translateImplicitConversion(e.Y, t))
			}
		default:
			panic(e.Op)
		}

	case *ast.ParenExpr:
		x := c.translateExpr(e.X)
		if x.String() == "true" || x.String() == "false" {
			return x
		}
		return c.formatParenExpr("%s", x)

	case *ast.IndexExpr:
		switch t := c.p.info.Types[e.X].Type.Underlying().(type) {
		case *types.Array, *types.Pointer:
			if c.p.info.Types[e.Index].Value != nil {
				return c.formatExpr("%e[%f]", e.X, e.Index)
			}
			return c.formatExpr(`((%2f < 0 || %2f >= %1e.length) ? $throwRuntimeError("index out of range") : %1e[%2f])`, e.X, e.Index)
		case *types.Slice:
			return c.formatExpr(`((%2f < 0 || %2f >= %1e.$length) ? $throwRuntimeError("index out of range") : %1e.$array[%1e.$offset + %2f])`, e.X, e.Index)
		case *types.Map:
			key := c.makeKey(e.Index, t.Key())
			if _, isTuple := exprType.(*types.Tuple); isTuple {
				return c.formatExpr(`(%1s = %2e[%3s], %1s !== undefined ? [%1s.v, true] : [%4s, false])`, c.newVariable("_entry"), e.X, key, c.zeroValue(t.Elem()))
			}
			return c.formatExpr(`(%1s = %2e[%3s], %1s !== undefined ? %1s.v : %4s)`, c.newVariable("_entry"), e.X, key, c.zeroValue(t.Elem()))
		case *types.Basic:
			return c.formatExpr("%e.charCodeAt(%f)", e.X, e.Index)
		default:
			panic(fmt.Sprintf("Unhandled IndexExpr: %T\n", t))
		}

	case *ast.SliceExpr:
		if b, isBasic := c.p.info.Types[e.X].Type.Underlying().(*types.Basic); isBasic && b.Info()&types.IsString != 0 {
			switch {
			case e.Low == nil && e.High == nil:
				return c.translateExpr(e.X)
			case e.Low == nil:
				return c.formatExpr("%e.substring(0, %f)", e.X, e.High)
			case e.High == nil:
				return c.formatExpr("%e.substring(%f)", e.X, e.Low)
			default:
				return c.formatExpr("%e.substring(%f, %f)", e.X, e.Low, e.High)
			}
		}
		slice := c.translateConversionToSlice(e.X, exprType)
		switch {
		case e.Low == nil && e.High == nil:
			return c.formatExpr("%s", slice)
		case e.Low == nil:
			if e.Max != nil {
				return c.formatExpr("$subslice(%s, 0, %f, %f)", slice, e.High, e.Max)
			}
			return c.formatExpr("$subslice(%s, 0, %f)", slice, e.High)
		case e.High == nil:
			return c.formatExpr("$subslice(%s, %f)", slice, e.Low)
		default:
			if e.Max != nil {
				return c.formatExpr("$subslice(%s, %f, %f, %f)", slice, e.Low, e.High, e.Max)
			}
			return c.formatExpr("$subslice(%s, %f, %f)", slice, e.Low, e.High)
		}

	case *ast.SelectorExpr:
		sel, ok := c.p.info.Selections[e]
		if !ok {
			// qualified identifier
			obj := c.p.info.Uses[e.Sel]
			if isJsPackage(obj.Pkg()) {
				switch obj.Name() {
				case "Global":
					return c.formatExpr("$global")
				case "This":
					if len(c.flattened) != 0 {
						return c.formatExpr("$this")
					}
					return c.formatExpr("this")
				case "Arguments":
					args := "arguments"
					if len(c.flattened) != 0 {
						args = "$args"
					}
					return c.formatExpr(`new ($sliceType(%s.Object))($global.Array.prototype.slice.call(%s, []))`, c.p.pkgVars["github.com/gopherjs/gopherjs/js"], args)
				case "Module":
					return c.formatExpr("$module")
				default:
					panic("Invalid js package object: " + obj.Name())
				}
			}
			return c.formatExpr("%s", c.objectName(obj))
		}

		parameterName := func(v *types.Var) string {
			if v.Anonymous() || v.Name() == "" {
				return c.newVariable("param")
			}
			return c.newVariable(v.Name())
		}
		makeParametersList := func() []string {
			params := sel.Obj().Type().(*types.Signature).Params()
			names := make([]string, params.Len())
			for i := 0; i < params.Len(); i++ {
				names[i] = parameterName(params.At(i))
			}
			return names
		}

		switch sel.Kind() {
		case types.FieldVal:
			fields, jsTag := c.translateSelection(sel)
			if jsTag != "" {
				if _, ok := sel.Type().(*types.Signature); ok {
					return c.formatExpr("$internalize(%1e.%2s.%3s, %4s, %1e.%2s)", e.X, strings.Join(fields, "."), jsTag, c.typeName(sel.Type()))
				}
				return c.internalize(c.formatExpr("%e.%s.%s", e.X, strings.Join(fields, "."), jsTag), sel.Type())
			}
			return c.formatExpr("%e.%s", e.X, strings.Join(fields, "."))
		case types.MethodVal:
			if !sel.Obj().Exported() {
				c.p.dependencies[sel.Obj()] = true
			}
			parameters := makeParametersList()
			target := c.translateExpr(e.X)
			if isWrapped(sel.Recv()) {
				target = c.formatParenExpr("new %s(%s)", c.typeName(sel.Recv()), target)
			}
			recv := c.newVariable("_recv")
			return c.formatExpr("(%s = %s, function(%s) { $stackDepthOffset--; try { return %s.%s(%s); } finally { $stackDepthOffset++; } })", recv, target, strings.Join(parameters, ", "), recv, e.Sel.Name, strings.Join(parameters, ", "))
		case types.MethodExpr:
			if !sel.Obj().Exported() {
				c.p.dependencies[sel.Obj()] = true
			}
			recv := "recv"
			if isWrapped(sel.Recv()) {
				recv = fmt.Sprintf("(new %s(recv))", c.typeName(sel.Recv()))
			}
			parameters := makeParametersList()
			return c.formatExpr("(function(%s) { $stackDepthOffset--; try { return %s.%s(%s); } finally { $stackDepthOffset++; } })", strings.Join(append([]string{"recv"}, parameters...), ", "), recv, sel.Obj().(*types.Func).Name(), strings.Join(parameters, ", "))
		}
		panic("")

	case *ast.CallExpr:
		plainFun := e.Fun
		for {
			if p, isParen := plainFun.(*ast.ParenExpr); isParen {
				plainFun = p.X
				continue
			}
			break
		}

		var isType func(ast.Expr) bool
		isType = func(expr ast.Expr) bool {
			switch e := expr.(type) {
			case *ast.ArrayType, *ast.ChanType, *ast.FuncType, *ast.InterfaceType, *ast.MapType, *ast.StructType:
				return true
			case *ast.StarExpr:
				return isType(e.X)
			case *ast.Ident:
				_, ok := c.p.info.Uses[e].(*types.TypeName)
				return ok
			case *ast.SelectorExpr:
				_, ok := c.p.info.Uses[e.Sel].(*types.TypeName)
				return ok
			case *ast.ParenExpr:
				return isType(e.X)
			default:
				return false
			}
		}

		if isType(plainFun) {
			return c.formatExpr("%s", c.translateConversion(e.Args[0], c.p.info.Types[plainFun].Type))
		}

		var fun *expression
		switch f := plainFun.(type) {
		case *ast.Ident:
			if o, ok := c.p.info.Uses[f].(*types.Builtin); ok {
				return c.translateBuiltin(o.Name(), e.Args, e.Ellipsis.IsValid(), exprType)
			}
			fun = c.translateExpr(plainFun)

		case *ast.SelectorExpr:
			sel, ok := c.p.info.Selections[f]
			if !ok {
				// qualified identifier
				obj := c.p.info.Uses[f.Sel]
				if isJsPackage(obj.Pkg()) {
					switch obj.Name() {
					case "InternalObject":
						return c.translateExpr(e.Args[0])
					}
				}
				fun = c.translateExpr(f)
				break
			}

			externalizeExpr := func(e ast.Expr) string {
				t := c.p.info.Types[e].Type
				if types.Identical(t, types.Typ[types.UntypedNil]) {
					return "null"
				}
				return c.externalize(c.translateExpr(e).String(), t)
			}
			externalizeArgs := func(args []ast.Expr) string {
				s := make([]string, len(args))
				for i, arg := range args {
					s[i] = externalizeExpr(arg)
				}
				return strings.Join(s, ", ")
			}

			switch sel.Kind() {
			case types.MethodVal:
				if !sel.Obj().Exported() {
					c.p.dependencies[sel.Obj()] = true
				}

				methodName := sel.Obj().Name()
				if reservedKeywords[methodName] {
					methodName += "$"
				}

				recvType := sel.Recv()
				_, isPointer := recvType.Underlying().(*types.Pointer)
				methodsRecvType := sel.Obj().Type().(*types.Signature).Recv().Type()
				_, pointerExpected := methodsRecvType.(*types.Pointer)
				var recv *expression
				switch {
				case !isPointer && pointerExpected:
					recv = c.translateExpr(c.setType(&ast.UnaryExpr{Op: token.AND, X: f.X}, methodsRecvType))
				default:
					recv = c.translateExpr(f.X)
				}

				for _, index := range sel.Index()[:len(sel.Index())-1] {
					if ptr, isPtr := recvType.(*types.Pointer); isPtr {
						recvType = ptr.Elem()
					}
					s := recvType.Underlying().(*types.Struct)
					recv = c.formatExpr("%s.%s", recv, fieldName(s, index))
					recvType = s.Field(index).Type()
				}

				if isJsPackage(sel.Obj().Pkg()) {
					globalRef := func(id string) string {
						if recv.String() == "$global" && id[0] == '$' {
							return id
						}
						return recv.String() + "." + id
					}
					switch sel.Obj().Name() {
					case "Get":
						if id, ok := c.identifierConstant(e.Args[0]); ok {
							return c.formatExpr("%s", globalRef(id))
						}
						return c.formatExpr("%s[$externalize(%e, $String)]", recv, e.Args[0])
					case "Set":
						if id, ok := c.identifierConstant(e.Args[0]); ok {
							return c.formatExpr("%s = %s", globalRef(id), externalizeExpr(e.Args[1]))
						}
						return c.formatExpr("%s[$externalize(%e, $String)] = %s", recv, e.Args[0], externalizeExpr(e.Args[1]))
					case "Delete":
						return c.formatExpr("delete %s[$externalize(%e, $String)]", recv, e.Args[0])
					case "Length":
						return c.formatExpr("$parseInt(%s.length)", recv)
					case "Index":
						return c.formatExpr("%s[%e]", recv, e.Args[0])
					case "SetIndex":
						return c.formatExpr("%s[%e] = %s", recv, e.Args[0], externalizeExpr(e.Args[1]))
					case "Call":
						if id, ok := c.identifierConstant(e.Args[0]); ok {
							if e.Ellipsis.IsValid() {
								objVar := c.newVariable("obj")
								return c.formatExpr("(%s = %s, %s.%s.apply(%s, %s))", objVar, recv, objVar, id, objVar, externalizeExpr(e.Args[1]))
							}
							return c.formatExpr("%s(%s)", globalRef(id), externalizeArgs(e.Args[1:]))
						}
						if e.Ellipsis.IsValid() {
							objVar := c.newVariable("obj")
							return c.formatExpr("(%s = %s, %s[$externalize(%e, $String)].apply(%s, %s))", objVar, recv, objVar, e.Args[0], objVar, externalizeExpr(e.Args[1]))
						}
						return c.formatExpr("%s[$externalize(%e, $String)](%s)", recv, e.Args[0], externalizeArgs(e.Args[1:]))
					case "Invoke":
						if e.Ellipsis.IsValid() {
							return c.formatExpr("%s.apply(undefined, %s)", recv, externalizeExpr(e.Args[0]))
						}
						return c.formatExpr("%s(%s)", recv, externalizeArgs(e.Args))
					case "New":
						if e.Ellipsis.IsValid() {
							return c.formatExpr("new ($global.Function.prototype.bind.apply(%s, [undefined].concat(%s)))", recv, externalizeExpr(e.Args[0]))
						}
						return c.formatExpr("new (%s)(%s)", recv, externalizeArgs(e.Args))
					case "Bool":
						return c.internalize(recv, types.Typ[types.Bool])
					case "Str":
						return c.internalize(recv, types.Typ[types.String])
					case "Int":
						return c.internalize(recv, types.Typ[types.Int])
					case "Int64":
						return c.internalize(recv, types.Typ[types.Int64])
					case "Uint64":
						return c.internalize(recv, types.Typ[types.Uint64])
					case "Float":
						return c.internalize(recv, types.Typ[types.Float64])
					case "Interface":
						return c.internalize(recv, types.NewInterface(nil, nil))
					case "Unsafe":
						return recv
					case "IsUndefined":
						return c.formatParenExpr("%s === undefined", recv)
					case "IsNull":
						return c.formatParenExpr("%s === null", recv)
					default:
						panic("Invalid js package object: " + sel.Obj().Name())
					}
				}

				if isWrapped(methodsRecvType) {
					fun = c.formatExpr("(new %s(%s)).%s", c.typeName(methodsRecvType), recv, methodName)
					break
				}
				fun = c.formatExpr("%s.%s", recv, methodName)

			case types.FieldVal:
				fields, jsTag := c.translateSelection(sel)
				if jsTag != "" {
					sig := sel.Type().(*types.Signature)
					return c.internalize(c.formatExpr("%e.%s.%s(%s)", f.X, strings.Join(fields, "."), jsTag, externalizeArgs(e.Args)), sig.Results().At(0).Type())
				}
				fun = c.formatExpr("%e.%s", f.X, strings.Join(fields, "."))

			case types.MethodExpr:
				fun = c.translateExpr(f)

			default:
				panic("")
			}
		default:
			fun = c.translateExpr(plainFun)
		}

		sig := c.p.info.Types[plainFun].Type.Underlying().(*types.Signature)
		if len(e.Args) == 1 {
			if tuple, isTuple := c.p.info.Types[e.Args[0]].Type.(*types.Tuple); isTuple {
				tupleVar := c.newVariable("_tuple")
				args := make([]ast.Expr, tuple.Len())
				for i := range args {
					args[i] = c.newIdent(c.formatExpr("%s[%d]", tupleVar, i).String(), tuple.At(i).Type())
				}
				return c.formatExpr("(%s = %e, %s(%s))", tupleVar, e.Args[0], fun, strings.Join(c.translateArgs(sig, args, false), ", "))
			}
		}
		args := c.translateArgs(sig, e.Args, e.Ellipsis.IsValid())
		if c.blocking[e] {
			resumeCase := c.caseCounter
			c.caseCounter++
			returnVar := "$r"
			if sig.Results().Len() != 0 {
				returnVar = c.newVariable("_r")
			}
			c.Printf("%[1]s = %[2]s(%[3]s); /* */ $s = %[4]d; case %[4]d: if (%[1]s && %[1]s.constructor === Function) { %[1]s = %[1]s(); }", returnVar, fun, strings.Join(append(args, "true"), ", "), resumeCase)
			if sig.Results().Len() != 0 {
				return c.formatExpr("%s", returnVar)
			}
			return nil
		}
		return c.formatExpr("%s(%s)", fun, strings.Join(args, ", "))

	case *ast.StarExpr:
		if c1, isCall := e.X.(*ast.CallExpr); isCall && len(c1.Args) == 1 {
			if c2, isCall := c1.Args[0].(*ast.CallExpr); isCall && len(c2.Args) == 1 && types.Identical(c.p.info.Types[c2.Fun].Type, types.Typ[types.UnsafePointer]) {
				if unary, isUnary := c2.Args[0].(*ast.UnaryExpr); isUnary && unary.Op == token.AND {
					return c.translateExpr(unary.X) // unsafe conversion
				}
			}
		}
		switch exprType.Underlying().(type) {
		case *types.Struct, *types.Array:
			return c.translateExpr(e.X)
		}
		return c.formatExpr("%e.$get()", e.X)

	case *ast.TypeAssertExpr:
		if e.Type == nil {
			return c.translateExpr(e.X)
		}
		t := c.p.info.Types[e.Type].Type
		check := "%1e !== null && " + c.typeCheck("%1e.constructor", t)
		valueSuffix := ""
		if _, isInterface := t.Underlying().(*types.Interface); !isInterface {
			valueSuffix = ".$val"
		}
		if _, isTuple := exprType.(*types.Tuple); isTuple {
			return c.formatExpr("("+check+" ? [%1e%2s, true] : [%3s, false])", e.X, valueSuffix, c.zeroValue(c.p.info.Types[e.Type].Type))
		}
		return c.formatExpr("("+check+" ? %1e%2s : $typeAssertionFailed(%1e, %3s))", e.X, valueSuffix, c.typeName(t))

	case *ast.Ident:
		if e.Name == "_" {
			panic("Tried to translate underscore identifier.")
		}
		obj := c.p.info.Defs[e]
		if obj == nil {
			obj = c.p.info.Uses[e]
		}
		switch o := obj.(type) {
		case *types.PkgName:
			return c.formatExpr("%s", c.p.pkgVars[o.Pkg().Path()])
		case *types.Var, *types.Const:
			return c.formatExpr("%s", c.objectName(o))
		case *types.Func:
			return c.formatExpr("%s", c.objectName(o))
		case *types.TypeName:
			return c.formatExpr("%s", c.typeName(o.Type()))
		case *types.Nil:
			return c.formatExpr("%s", c.zeroValue(c.p.info.Types[e].Type))
		default:
			panic(fmt.Sprintf("Unhandled object: %T\n", o))
		}

	case *This:
		this := "this"
		if len(c.flattened) != 0 {
			this = "$this"
		}
		if isWrapped(c.p.info.Types[e].Type) {
			this += ".$val"
		}
		return c.formatExpr(this)

	case nil:
		return c.formatExpr("")

	default:
		panic(fmt.Sprintf("Unhandled expression: %T\n", e))

	}
}
Esempio n. 18
0
func (c *PkgContext) translateMethod(typeName string, isStruct bool, fun *ast.FuncDecl) {
	c.newScope(func() {
		sig := c.info.Objects[fun.Name].(*types.Func).Type().(*types.Signature)
		recvType := sig.Recv().Type()
		ptr, isPointer := recvType.(*types.Pointer)

		params := c.translateParams(fun.Type)
		joinedParams := strings.Join(params, ", ")
		printPrimaryFunction := func(lhs string) {
			c.Printf("%s = function(%s) {", lhs, joinedParams)
			c.Indent(func() {
				if jsCode, ok := c.pkg.Scope().Lookup("js_" + typeName + "_" + fun.Name.Name).(*types.Const); ok {
					c.Write([]byte(exact.StringVal(jsCode.Val())))
					c.Write([]byte{'\n'})
					return
				}
				if fun.Body == nil {
					c.Printf(`throw new Go$Panic("Native function not implemented: %s.%s");`, typeName, fun.Name.Name)
					return
				}

				body := fun.Body.List
				if fun.Recv.List[0].Names != nil {
					recv := fun.Recv.List[0].Names[0]
					c.info.Types[recv] = recvType
					this := c.newIdent("this", recvType)
					if isWrapped(recvType) {
						this = c.newIdent("this.Go$val", recvType)
					}
					body = append([]ast.Stmt{
						&ast.AssignStmt{
							Lhs: []ast.Expr{recv},
							Tok: token.DEFINE,
							Rhs: []ast.Expr{this},
						},
					}, body...)
				}

				c.translateFunctionBody(body, sig)
			})
			c.Printf("};")
		}

		switch {
		case isStruct:
			printPrimaryFunction(typeName + ".prototype." + fun.Name.Name)
			c.Printf("%s.Go$NonPointer.prototype.%s = function(%s) { return this.Go$val.%s(%s); };", typeName, fun.Name.Name, joinedParams, fun.Name.Name, joinedParams)
		case !isStruct && !isPointer:
			value := "this.Go$get()"
			if isWrapped(recvType) {
				value = fmt.Sprintf("new %s(%s)", typeName, value)
			}
			printPrimaryFunction(typeName + ".prototype." + fun.Name.Name)
			c.Printf("%s.Go$Pointer.prototype.%s = function(%s) { return %s.%s(%s); };", typeName, fun.Name.Name, joinedParams, value, fun.Name.Name, joinedParams)
		case !isStruct && isPointer:
			if _, isArray := ptr.Elem().Underlying().(*types.Array); isArray {
				printPrimaryFunction(typeName + ".prototype." + fun.Name.Name)
				break
			}
			value := "this"
			if isWrapped(ptr.Elem()) {
				value = "this.Go$val"
			}
			c.Printf("%s.prototype.%s = function(%s) { var obj = %s; return (new %s.Go$Pointer(function() { return obj; }, null)).%s(%s); };", typeName, fun.Name.Name, joinedParams, value, typeName, fun.Name.Name, joinedParams)
			printPrimaryFunction(typeName + ".Go$Pointer.prototype." + fun.Name.Name)
		}
	})
}
Esempio n. 19
0
// builtin type-checks a call to the built-in specified by id and
// returns true if the call is valid, with *x holding the result;
// but x.expr is not set. If the call is invalid, the result is
// false, and *x is undefined.
//
func (check *Checker) builtin(x *operand, call *ast.CallExpr, id builtinId) (_ bool) {
	// append is the only built-in that permits the use of ... for the last argument
	bin := predeclaredFuncs[id]
	if call.Ellipsis.IsValid() && id != _Append {
		check.invalidOp(call.Ellipsis, "invalid use of ... with built-in %s", bin.name)
		check.use(call.Args...)
		return
	}

	// For len(x) and cap(x) we need to know if x contains any function calls or
	// receive operations. Save/restore current setting and set hasCallOrRecv to
	// false for the evaluation of x so that we can check it afterwards.
	// Note: We must do this _before_ calling unpack because unpack evaluates the
	//       first argument before we even call arg(x, 0)!
	if id == _Len || id == _Cap {
		defer func(b bool) {
			check.hasCallOrRecv = b
		}(check.hasCallOrRecv)
		check.hasCallOrRecv = false
	}

	// determine actual arguments
	var arg getter
	nargs := len(call.Args)
	switch id {
	default:
		// make argument getter
		arg, nargs, _ = unpack(func(x *operand, i int) { check.expr(x, call.Args[i]) }, nargs, false)
		// evaluate first argument, if present
		if nargs > 0 {
			arg(x, 0)
			if x.mode == invalid {
				return
			}
		}
	case _Make, _New, _Offsetof, _Trace:
		// arguments require special handling
	}

	// check argument count
	{
		msg := ""
		if nargs < bin.nargs {
			msg = "not enough"
		} else if !bin.variadic && nargs > bin.nargs {
			msg = "too many"
		}
		if msg != "" {
			check.invalidOp(call.Rparen, "%s arguments for %s (expected %d, found %d)", msg, call, bin.nargs, nargs)
			return
		}
	}

	switch id {
	case _Append:
		// append(s S, x ...T) S, where T is the element type of S
		// spec: "The variadic function append appends zero or more values x to s of type
		// S, which must be a slice type, and returns the resulting slice, also of type S.
		// The values x are passed to a parameter of type ...T where T is the element type
		// of S and the respective parameter passing rules apply."
		S := x.typ
		var T Type
		if s, _ := S.Underlying().(*Slice); s != nil {
			T = s.elem
		} else {
			check.invalidArg(x.pos(), "%s is not a slice", x)
			return
		}

		// remember arguments that have been evaluated already
		alist := []operand{*x}

		// spec: "As a special case, append also accepts a first argument assignable
		// to type []byte with a second argument of string type followed by ... .
		// This form appends the bytes of the string.
		if nargs == 2 && call.Ellipsis.IsValid() && x.assignableTo(check.conf, NewSlice(UniverseByte)) {
			arg(x, 1)
			if x.mode == invalid {
				return
			}
			if isString(x.typ) {
				if check.Types != nil {
					sig := makeSig(S, S, x.typ)
					sig.variadic = true
					check.recordBuiltinType(call.Fun, sig)
				}
				x.mode = value
				x.typ = S
				break
			}
			alist = append(alist, *x)
			// fallthrough
		}

		// check general case by creating custom signature
		sig := makeSig(S, S, NewSlice(T)) // []T required for variadic signature
		sig.variadic = true
		check.arguments(x, call, sig, func(x *operand, i int) {
			// only evaluate arguments that have not been evaluated before
			if i < len(alist) {
				*x = alist[i]
				return
			}
			arg(x, i)
		}, nargs)
		// ok to continue even if check.arguments reported errors

		x.mode = value
		x.typ = S
		if check.Types != nil {
			check.recordBuiltinType(call.Fun, sig)
		}

	case _Cap, _Len:
		// cap(x)
		// len(x)
		mode := invalid
		var typ Type
		var val exact.Value
		switch typ = implicitArrayDeref(x.typ.Underlying()); t := typ.(type) {
		case *Basic:
			if isString(t) && id == _Len {
				if x.mode == constant {
					mode = constant
					val = exact.MakeInt64(int64(len(exact.StringVal(x.val))))
				} else {
					mode = value
				}
			}

		case *Array:
			mode = value
			// spec: "The expressions len(s) and cap(s) are constants
			// if the type of s is an array or pointer to an array and
			// the expression s does not contain channel receives or
			// function calls; in this case s is not evaluated."
			if !check.hasCallOrRecv {
				mode = constant
				val = exact.MakeInt64(t.len)
			}

		case *Slice, *Chan:
			mode = value

		case *Map:
			if id == _Len {
				mode = value
			}
		}

		if mode == invalid {
			check.invalidArg(x.pos(), "%s for %s", x, bin.name)
			return
		}

		x.mode = mode
		x.typ = Typ[Int]
		x.val = val
		if check.Types != nil && mode != constant {
			check.recordBuiltinType(call.Fun, makeSig(x.typ, typ))
		}

	case _Close:
		// close(c)
		c, _ := x.typ.Underlying().(*Chan)
		if c == nil {
			check.invalidArg(x.pos(), "%s is not a channel", x)
			return
		}
		if c.dir == RecvOnly {
			check.invalidArg(x.pos(), "%s must not be a receive-only channel", x)
			return
		}

		x.mode = novalue
		if check.Types != nil {
			check.recordBuiltinType(call.Fun, makeSig(nil, c))
		}

	case _Complex:
		// complex(x, y realT) complexT
		if !check.complexArg(x) {
			return
		}

		var y operand
		arg(&y, 1)
		if y.mode == invalid {
			return
		}
		if !check.complexArg(&y) {
			return
		}

		check.convertUntyped(x, y.typ)
		if x.mode == invalid {
			return
		}
		check.convertUntyped(&y, x.typ)
		if y.mode == invalid {
			return
		}

		if !Identical(x.typ, y.typ) {
			check.invalidArg(x.pos(), "mismatched types %s and %s", x.typ, y.typ)
			return
		}

		if x.mode == constant && y.mode == constant {
			x.val = exact.BinaryOp(x.val, token.ADD, exact.MakeImag(y.val))
		} else {
			x.mode = value
		}

		realT := x.typ
		complexT := Typ[Invalid]
		switch realT.Underlying().(*Basic).kind {
		case Float32:
			complexT = Typ[Complex64]
		case Float64:
			complexT = Typ[Complex128]
		case UntypedInt, UntypedRune, UntypedFloat:
			if x.mode == constant {
				realT = defaultType(realT).(*Basic)
				complexT = Typ[UntypedComplex]
			} else {
				// untyped but not constant; probably because one
				// operand is a non-constant shift of untyped lhs
				realT = Typ[Float64]
				complexT = Typ[Complex128]
			}
		default:
			check.invalidArg(x.pos(), "float32 or float64 arguments expected")
			return
		}

		x.typ = complexT
		if check.Types != nil && x.mode != constant {
			check.recordBuiltinType(call.Fun, makeSig(complexT, realT, realT))
		}

		if x.mode != constant {
			// The arguments have now their final types, which at run-
			// time will be materialized. Update the expression trees.
			// If the current types are untyped, the materialized type
			// is the respective default type.
			// (If the result is constant, the arguments are never
			// materialized and there is nothing to do.)
			check.updateExprType(x.expr, realT, true)
			check.updateExprType(y.expr, realT, true)
		}

	case _Copy:
		// copy(x, y []T) int
		var dst Type
		if t, _ := x.typ.Underlying().(*Slice); t != nil {
			dst = t.elem
		}

		var y operand
		arg(&y, 1)
		if y.mode == invalid {
			return
		}
		var src Type
		switch t := y.typ.Underlying().(type) {
		case *Basic:
			if isString(y.typ) {
				src = UniverseByte
			}
		case *Slice:
			src = t.elem
		}

		if dst == nil || src == nil {
			check.invalidArg(x.pos(), "copy expects slice arguments; found %s and %s", x, &y)
			return
		}

		if !Identical(dst, src) {
			check.invalidArg(x.pos(), "arguments to copy %s and %s have different element types %s and %s", x, &y, dst, src)
			return
		}

		if check.Types != nil {
			check.recordBuiltinType(call.Fun, makeSig(Typ[Int], x.typ, y.typ))
		}
		x.mode = value
		x.typ = Typ[Int]

	case _Delete:
		// delete(m, k)
		m, _ := x.typ.Underlying().(*Map)
		if m == nil {
			check.invalidArg(x.pos(), "%s is not a map", x)
			return
		}
		arg(x, 1) // k
		if x.mode == invalid {
			return
		}

		if !x.assignableTo(check.conf, m.key) {
			check.invalidArg(x.pos(), "%s is not assignable to %s", x, m.key)
			return
		}

		x.mode = novalue
		if check.Types != nil {
			check.recordBuiltinType(call.Fun, makeSig(nil, m, m.key))
		}

	case _Imag, _Real:
		// imag(complexT) realT
		// real(complexT) realT
		if !isComplex(x.typ) {
			check.invalidArg(x.pos(), "%s must be a complex number", x)
			return
		}
		if x.mode == constant {
			if id == _Real {
				x.val = exact.Real(x.val)
			} else {
				x.val = exact.Imag(x.val)
			}
		} else {
			x.mode = value
		}
		var k BasicKind
		switch x.typ.Underlying().(*Basic).kind {
		case Complex64:
			k = Float32
		case Complex128:
			k = Float64
		case UntypedComplex:
			k = UntypedFloat
		default:
			unreachable()
		}

		if check.Types != nil && x.mode != constant {
			check.recordBuiltinType(call.Fun, makeSig(Typ[k], x.typ))
		}
		x.typ = Typ[k]

	case _Make:
		// make(T, n)
		// make(T, n, m)
		// (no argument evaluated yet)
		arg0 := call.Args[0]
		T := check.typ(arg0)
		if T == Typ[Invalid] {
			return
		}
		var min int // minimum number of arguments
		switch T.Underlying().(type) {
		case *Slice:
			min = 2
		case *Map, *Chan:
			min = 1
		default:
			check.invalidArg(arg0.Pos(), "cannot make %s; type must be slice, map, or channel", arg0)
			return
		}
		if nargs < min || min+1 < nargs {
			check.errorf(call.Pos(), "%s expects %d or %d arguments; found %d", call, min, min+1, nargs)
			return
		}
		var sizes []int64 // constant integer arguments, if any
		for _, arg := range call.Args[1:] {
			if s, ok := check.index(arg, -1); ok && s >= 0 {
				sizes = append(sizes, s)
			}
		}
		if len(sizes) == 2 && sizes[0] > sizes[1] {
			check.invalidArg(call.Args[1].Pos(), "length and capacity swapped")
			// safe to continue
		}
		x.mode = value
		x.typ = T
		if check.Types != nil {
			params := [...]Type{T, Typ[Int], Typ[Int]}
			check.recordBuiltinType(call.Fun, makeSig(x.typ, params[:1+len(sizes)]...))
		}

	case _New:
		// new(T)
		// (no argument evaluated yet)
		T := check.typ(call.Args[0])
		if T == Typ[Invalid] {
			return
		}

		x.mode = value
		x.typ = &Pointer{base: T}
		if check.Types != nil {
			check.recordBuiltinType(call.Fun, makeSig(x.typ, T))
		}

	case _Panic:
		// panic(x)
		T := new(Interface)
		if !check.assignment(x, T) {
			assert(x.mode == invalid)
			return
		}

		x.mode = novalue
		if check.Types != nil {
			check.recordBuiltinType(call.Fun, makeSig(nil, T))
		}

	case _Print, _Println:
		// print(x, y, ...)
		// println(x, y, ...)
		var params []Type
		if nargs > 0 {
			params = make([]Type, nargs)
			for i := 0; i < nargs; i++ {
				if i > 0 {
					arg(x, i) // first argument already evaluated
				}
				if !check.assignment(x, nil) {
					assert(x.mode == invalid)
					return
				}
				params[i] = x.typ
			}
		}

		x.mode = novalue
		if check.Types != nil {
			check.recordBuiltinType(call.Fun, makeSig(nil, params...))
		}

	case _Recover:
		// recover() interface{}
		x.mode = value
		x.typ = new(Interface)
		if check.Types != nil {
			check.recordBuiltinType(call.Fun, makeSig(x.typ))
		}

	case _Alignof:
		// unsafe.Alignof(x T) uintptr
		if !check.assignment(x, nil) {
			assert(x.mode == invalid)
			return
		}

		x.mode = constant
		x.val = exact.MakeInt64(check.conf.alignof(x.typ))
		x.typ = Typ[Uintptr]
		// result is constant - no need to record signature

	case _Offsetof:
		// unsafe.Offsetof(x T) uintptr, where x must be a selector
		// (no argument evaluated yet)
		arg0 := call.Args[0]
		selx, _ := unparen(arg0).(*ast.SelectorExpr)
		if selx == nil {
			check.invalidArg(arg0.Pos(), "%s is not a selector expression", arg0)
			check.use(arg0)
			return
		}
		check.expr(x, selx.X)
		if x.mode == invalid {
			return
		}
		base := derefStructPtr(x.typ)
		sel := selx.Sel.Name
		obj, index, indirect := LookupFieldOrMethod(base, false, check.pkg, sel)
		switch obj.(type) {
		case nil:
			check.invalidArg(x.pos(), "%s has no single field %s", base, sel)
			return
		case *Func:
			// TODO(gri) Using derefStructPtr may result in methods being found
			// that don't actually exist. An error either way, but the error
			// message is confusing. See: http://play.golang.org/p/al75v23kUy ,
			// but go/types reports: "invalid argument: x.m is a method value".
			check.invalidArg(arg0.Pos(), "%s is a method value", arg0)
			return
		}
		if indirect {
			check.invalidArg(x.pos(), "field %s is embedded via a pointer in %s", sel, base)
			return
		}

		// TODO(gri) Should we pass x.typ instead of base (and indirect report if derefStructPtr indirected)?
		check.recordSelection(selx, FieldVal, base, obj, index, false)

		offs := check.conf.offsetof(base, index)
		x.mode = constant
		x.val = exact.MakeInt64(offs)
		x.typ = Typ[Uintptr]
		// result is constant - no need to record signature

	case _Sizeof:
		// unsafe.Sizeof(x T) uintptr
		if !check.assignment(x, nil) {
			assert(x.mode == invalid)
			return
		}

		x.mode = constant
		x.val = exact.MakeInt64(check.conf.sizeof(x.typ))
		x.typ = Typ[Uintptr]
		// result is constant - no need to record signature

	case _Assert:
		// assert(pred) causes a typechecker error if pred is false.
		// The result of assert is the value of pred if there is no error.
		// Note: assert is only available in self-test mode.
		if x.mode != constant || !isBoolean(x.typ) {
			check.invalidArg(x.pos(), "%s is not a boolean constant", x)
			return
		}
		if x.val.Kind() != exact.Bool {
			check.errorf(x.pos(), "internal error: value of %s should be a boolean constant", x)
			return
		}
		if !exact.BoolVal(x.val) {
			check.errorf(call.Pos(), "%s failed", call)
			// compile-time assertion failure - safe to continue
		}
		// result is constant - no need to record signature

	case _Trace:
		// trace(x, y, z, ...) dumps the positions, expressions, and
		// values of its arguments. The result of trace is the value
		// of the first argument.
		// Note: trace is only available in self-test mode.
		// (no argument evaluated yet)
		if nargs == 0 {
			check.dump("%s: trace() without arguments", call.Pos())
			x.mode = novalue
			break
		}
		var t operand
		x1 := x
		for _, arg := range call.Args {
			check.rawExpr(x1, arg, nil) // permit trace for types, e.g.: new(trace(T))
			check.dump("%s: %s", x1.pos(), x1)
			x1 = &t // use incoming x only for first argument
		}
		// trace is only available in test mode - no need to record signature

	default:
		unreachable()
	}

	return true
}
Esempio n. 20
0
func TranslatePackage(importPath string, files []*ast.File, fileSet *token.FileSet, config *types.Config) ([]byte, error) {
	info := &types.Info{
		Types:      make(map[ast.Expr]types.Type),
		Values:     make(map[ast.Expr]exact.Value),
		Objects:    make(map[*ast.Ident]types.Object),
		Implicits:  make(map[ast.Node]types.Object),
		Selections: make(map[*ast.SelectorExpr]*types.Selection),
	}

	var errList ErrorList
	var previousErr error
	config.Error = func(err error) {
		if previousErr != nil && previousErr.Error() == err.Error() {
			return
		}
		errList = append(errList, err)
		previousErr = err
	}
	config.Sizes = sizes32
	typesPkg, err := config.Check(importPath, fileSet, files, info)
	if errList != nil {
		return nil, errList
	}
	if err != nil {
		return nil, err
	}
	config.Packages[importPath] = typesPkg

	c := &PkgContext{
		pkg:          typesPkg,
		info:         info,
		pkgVars:      make(map[string]string),
		objectVars:   make(map[types.Object]string),
		allVarNames:  make(map[string]int),
		postLoopStmt: make(map[string]ast.Stmt),
		positions:    make(map[int]token.Pos),
	}
	for _, name := range ReservedKeywords {
		c.allVarNames[name] = 1
	}

	functionsByType := make(map[types.Type][]*ast.FuncDecl)
	functionsByObject := make(map[types.Object]*ast.FuncDecl)
	var initStmts []ast.Stmt
	var typeSpecs []*ast.TypeSpec
	var constSpecs []*ast.ValueSpec
	var varSpecs []*ast.ValueSpec
	for _, file := range files {
		for _, decl := range file.Decls {
			switch d := decl.(type) {
			case *ast.FuncDecl:
				sig := c.info.Objects[d.Name].(*types.Func).Type().(*types.Signature)
				var recvType types.Type
				if sig.Recv() != nil {
					recvType = sig.Recv().Type()
					if ptr, isPtr := recvType.(*types.Pointer); isPtr {
						recvType = ptr.Elem()
					}
				}
				if sig.Recv() == nil && d.Name.Name == "init" {
					initStmts = append(initStmts, d.Body.List...)
					continue
				}
				functionsByType[recvType] = append(functionsByType[recvType], d)
				o := c.info.Objects[d.Name]
				functionsByObject[o] = d
				if sig.Recv() == nil {
					c.objectName(o) // register toplevel name
				}
			case *ast.GenDecl:
				switch d.Tok {
				case token.TYPE:
					for _, spec := range d.Specs {
						s := spec.(*ast.TypeSpec)
						typeSpecs = append(typeSpecs, s)
						c.objectName(c.info.Objects[s.Name]) // register toplevel name
					}
				case token.CONST:
					for _, spec := range d.Specs {
						s := spec.(*ast.ValueSpec)
						constSpecs = append(constSpecs, s)
						for _, name := range s.Names {
							if !isBlank(name) {
								c.objectName(c.info.Objects[name]) // register toplevel name
							}
						}
					}
				case token.VAR:
					for _, spec := range d.Specs {
						s := spec.(*ast.ValueSpec)
						varSpecs = append(varSpecs, s)
						for _, name := range s.Names {
							if !isBlank(name) {
								c.objectName(c.info.Objects[name]) // register toplevel name
							}
						}
					}
				}
			}
		}
	}

	// resolve var dependencies
	var unorderedSingleVarSpecs []*ast.ValueSpec
	pendingObjects := make(map[types.Object]bool)
	for _, spec := range varSpecs {
		for _, singleSpec := range c.splitValueSpec(spec) {
			if singleSpec.Values[0] == nil {
				continue
			}
			unorderedSingleVarSpecs = append(unorderedSingleVarSpecs, singleSpec)
			for _, name := range singleSpec.Names {
				pendingObjects[c.info.Objects[name]] = true
			}
		}
	}
	complete := false
	var intVarStmts []ast.Stmt
	for !complete {
		complete = true
		for i, spec := range unorderedSingleVarSpecs {
			if spec == nil {
				continue
			}
			v := DependencyCollector{info: c.info, functions: functionsByObject}
			ast.Walk(&v, spec.Values[0])
			currentObjs := make(map[types.Object]bool)
			for _, name := range spec.Names {
				currentObjs[c.info.Objects[name]] = true
			}
			ready := true
			for _, dep := range v.dependencies {
				if currentObjs[dep] {
					return nil, fmt.Errorf("%s: initialization loop", fileSet.Position(dep.Pos()).String())
				}
				ready = ready && !pendingObjects[dep]
			}
			if !ready {
				complete = false
				continue
			}
			lhs := make([]ast.Expr, len(spec.Names))
			for i, name := range spec.Names {
				lhs[i] = name
				delete(pendingObjects, c.info.Objects[name])
			}
			intVarStmts = append(intVarStmts, &ast.AssignStmt{
				Lhs: lhs,
				Tok: token.DEFINE,
				Rhs: spec.Values,
			})
			unorderedSingleVarSpecs[i] = nil
		}
	}

	c.Indent(func() {
		for _, importedPkg := range typesPkg.Imports() {
			varName := c.newVariable(importedPkg.Name())
			c.Printf(`var %s = Go$packages["%s"];`, varName, importedPkg.Path())
			c.pkgVars[importedPkg.Path()] = varName
		}

		// types and their functions
		for _, spec := range typeSpecs {
			obj := c.info.Objects[spec.Name]
			typeName := c.objectName(obj)
			c.Printf("var %s;", typeName)
			c.translateTypeSpec(spec)
			for _, fun := range functionsByType[obj.Type()] {
				_, isStruct := obj.Type().Underlying().(*types.Struct)
				c.translateMethod(typeName, isStruct, fun)
			}
			c.Printf("Go$pkg.%s = %s;", typeName, typeName)
		}

		// package functions
		for _, fun := range functionsByType[nil] {
			if isBlank(fun.Name) {
				continue
			}
			c.newScope(func() {
				name := c.objectName(c.info.Objects[fun.Name])
				params := c.translateParams(fun.Type)
				c.Printf("var %s = function(%s) {", name, strings.Join(params, ", "))
				c.Indent(func() {
					jsCode, _ := typesPkg.Scope().Lookup("js_" + name).(*types.Const)
					if jsCode != nil {
						c.Write([]byte(exact.StringVal(jsCode.Val())))
						c.Write([]byte{'\n'})
						return
					}
					if fun.Body == nil {
						c.Printf(`throw new Go$Panic("Native function not implemented: %s");`, name)
						return
					}

					c.translateFunctionBody(fun.Body.List, c.info.Objects[fun.Name].Type().(*types.Signature))
				})
				c.Printf("};")
			})
		}

		// constants
		for _, spec := range constSpecs {
			for _, name := range spec.Names {
				if isBlank(name) || strings.HasPrefix(name.Name, "js_") {
					continue
				}
				o := c.info.Objects[name].(*types.Const)
				c.info.Types[name] = o.Type()
				c.info.Values[name] = o.Val()
				c.Printf("%s = %s;", c.objectName(o), c.translateExpr(name))
			}
		}

		// variables
		for _, spec := range varSpecs {
			for _, name := range spec.Names {
				o := c.info.Objects[name].(*types.Var)
				c.Printf("%s = %s;", c.objectName(o), c.zeroValue(o.Type()))
			}
		}

		// native implementations
		if native, hasNative := natives[importPath]; hasNative {
			c.Write([]byte(strings.TrimSpace(native)))
			c.Write([]byte{'\n'})
		}

		// exports for package functions
		for _, fun := range functionsByType[nil] {
			name := fun.Name.Name
			if fun.Name.IsExported() || name == "main" {
				c.Printf("Go$pkg.%s = %s;", name, name)
			}
		}

		// init function
		c.Printf("Go$pkg.init = function() {")
		c.Indent(func() {
			c.translateFunctionBody(append(intVarStmts, initStmts...), nil)
		})
		c.Printf("};")
	})

	return c.output, nil
}
Esempio n. 21
0
func (c *compiler) NewConstValue(v exact.Value, typ types.Type) *LLVMValue {
	switch {
	case v.Kind() == exact.Unknown:
		// TODO nil literals should be represented more appropriately once the exact-package supports it.
		llvmtyp := c.types.ToLLVM(typ)
		return c.NewValue(llvm.ConstNull(llvmtyp), typ)

	case isString(typ):
		if isUntyped(typ) {
			typ = types.Typ[types.String]
		}
		llvmtyp := c.types.ToLLVM(typ)
		strval := exact.StringVal(v)
		strlen := len(strval)
		i8ptr := llvm.PointerType(llvm.Int8Type(), 0)
		var ptr llvm.Value
		if strlen > 0 {
			init := llvm.ConstString(strval, false)
			ptr = llvm.AddGlobal(c.module.Module, init.Type(), "")
			ptr.SetInitializer(init)
			ptr = llvm.ConstBitCast(ptr, i8ptr)
		} else {
			ptr = llvm.ConstNull(i8ptr)
		}
		len_ := llvm.ConstInt(c.types.inttype, uint64(strlen), false)
		llvmvalue := llvm.Undef(llvmtyp)
		llvmvalue = llvm.ConstInsertValue(llvmvalue, ptr, []uint32{0})
		llvmvalue = llvm.ConstInsertValue(llvmvalue, len_, []uint32{1})
		return c.NewValue(llvmvalue, typ)

	case isInteger(typ):
		if isUntyped(typ) {
			typ = types.Typ[types.Int]
		}
		llvmtyp := c.types.ToLLVM(typ)
		var llvmvalue llvm.Value
		if isUnsigned(typ) {
			v, _ := exact.Uint64Val(v)
			llvmvalue = llvm.ConstInt(llvmtyp, v, false)
		} else {
			v, _ := exact.Int64Val(v)
			llvmvalue = llvm.ConstInt(llvmtyp, uint64(v), true)
		}
		return c.NewValue(llvmvalue, typ)

	case isBoolean(typ):
		if isUntyped(typ) {
			typ = types.Typ[types.Bool]
		}
		var llvmvalue llvm.Value
		if exact.BoolVal(v) {
			llvmvalue = llvm.ConstAllOnes(llvm.Int1Type())
		} else {
			llvmvalue = llvm.ConstNull(llvm.Int1Type())
		}
		return c.NewValue(llvmvalue, typ)

	case isFloat(typ):
		if isUntyped(typ) {
			typ = types.Typ[types.Float64]
		}
		llvmtyp := c.types.ToLLVM(typ)
		floatval, _ := exact.Float64Val(v)
		llvmvalue := llvm.ConstFloat(llvmtyp, floatval)
		return c.NewValue(llvmvalue, typ)

	case typ == types.Typ[types.UnsafePointer]:
		llvmtyp := c.types.ToLLVM(typ)
		v, _ := exact.Uint64Val(v)
		llvmvalue := llvm.ConstInt(llvmtyp, v, false)
		return c.NewValue(llvmvalue, typ)

	case isComplex(typ):
		if isUntyped(typ) {
			typ = types.Typ[types.Complex128]
		}
		llvmtyp := c.types.ToLLVM(typ)
		floattyp := llvmtyp.StructElementTypes()[0]
		llvmvalue := llvm.ConstNull(llvmtyp)
		realv := exact.Real(v)
		imagv := exact.Imag(v)
		realfloatval, _ := exact.Float64Val(realv)
		imagfloatval, _ := exact.Float64Val(imagv)
		llvmre := llvm.ConstFloat(floattyp, realfloatval)
		llvmim := llvm.ConstFloat(floattyp, imagfloatval)
		llvmvalue = llvm.ConstInsertValue(llvmvalue, llvmre, []uint32{0})
		llvmvalue = llvm.ConstInsertValue(llvmvalue, llvmim, []uint32{1})
		return c.NewValue(llvmvalue, typ)
	}

	// Special case for string -> [](byte|rune)
	if u, ok := typ.Underlying().(*types.Slice); ok && isInteger(u.Elem()) {
		if v.Kind() == exact.String {
			strval := c.NewConstValue(v, types.Typ[types.String])
			return strval.Convert(typ).(*LLVMValue)
		}
	}

	panic(fmt.Sprintf("unhandled: t=%s(%T), v=%v(%T)", c.types.TypeString(typ), typ, v, v))
}
Esempio n. 22
0
// constValue returns the value of the constant with the
// dynamic type tag appropriate for c.Type().
func constValue(c *ssa.Const) value {
	if c.IsNil() {
		return zero(c.Type()) // typed nil
	}

	// By destination type:
	switch t := c.Type().Underlying().(type) {
	case *types.Basic:
		// TODO(adonovan): eliminate untyped constants from SSA form.
		switch t.Kind() {
		case types.Bool, types.UntypedBool:
			return exact.BoolVal(c.Value)
		case types.Int, types.UntypedInt:
			// Assume sizeof(int) is same on host and target.
			return int(c.Int64())
		case types.Int8:
			return int8(c.Int64())
		case types.Int16:
			return int16(c.Int64())
		case types.Int32, types.UntypedRune:
			return int32(c.Int64())
		case types.Int64:
			return c.Int64()
		case types.Uint:
			// Assume sizeof(uint) is same on host and target.
			return uint(c.Uint64())
		case types.Uint8:
			return uint8(c.Uint64())
		case types.Uint16:
			return uint16(c.Uint64())
		case types.Uint32:
			return uint32(c.Uint64())
		case types.Uint64:
			return c.Uint64()
		case types.Uintptr:
			// Assume sizeof(uintptr) is same on host and target.
			return uintptr(c.Uint64())
		case types.Float32:
			return float32(c.Float64())
		case types.Float64, types.UntypedFloat:
			return c.Float64()
		case types.Complex64:
			return complex64(c.Complex128())
		case types.Complex128, types.UntypedComplex:
			return c.Complex128()
		case types.String, types.UntypedString:
			if c.Value.Kind() == exact.String {
				return exact.StringVal(c.Value)
			}
			return string(rune(c.Int64()))
		case types.UnsafePointer:
			panic("unsafe.Pointer constant") // not possible
		case types.UntypedNil:
			// nil was handled above.
		}

	case *types.Slice:
		switch et := t.Elem().Underlying().(type) {
		case *types.Basic:
			switch et.Kind() {
			case types.Byte: // string -> []byte
				var v []value
				for _, b := range []byte(exact.StringVal(c.Value)) {
					v = append(v, b)
				}
				return v
			case types.Rune: // string -> []rune
				var v []value
				for _, r := range []rune(exact.StringVal(c.Value)) {
					v = append(v, r)
				}
				return v
			}
		}
	}

	panic(fmt.Sprintf("constValue: Value.(type)=%T Type()=%s", c.Value, c.Type()))
}
Esempio n. 23
0
// exprInternal contains the core of type checking of expressions.
// Must only be called by rawExpr.
//
func (check *Checker) exprInternal(x *operand, e ast.Expr, hint Type) exprKind {
	// make sure x has a valid state in case of bailout
	// (was issue 5770)
	x.mode = invalid
	x.typ = Typ[Invalid]

	switch e := e.(type) {
	case *ast.BadExpr:
		goto Error // error was reported before

	case *ast.Ident:
		check.ident(x, e, nil, nil)

	case *ast.Ellipsis:
		// ellipses are handled explicitly where they are legal
		// (array composite literals and parameter lists)
		check.error(e.Pos(), "invalid use of '...'")
		goto Error

	case *ast.BasicLit:
		x.setConst(e.Kind, e.Value)
		if x.mode == invalid {
			check.invalidAST(e.Pos(), "invalid literal %v", e.Value)
			goto Error
		}

	case *ast.FuncLit:
		if sig, ok := check.typ(e.Type).(*Signature); ok {
			// Anonymous functions are considered part of the
			// init expression/func declaration which contains
			// them: use existing package-level declaration info.
			check.funcBody(check.decl, "", sig, e.Body)
			x.mode = value
			x.typ = sig
		} else {
			check.invalidAST(e.Pos(), "invalid function literal %s", e)
			goto Error
		}

	case *ast.CompositeLit:
		typ := hint
		openArray := false
		if e.Type != nil {
			// [...]T array types may only appear with composite literals.
			// Check for them here so we don't have to handle ... in general.
			typ = nil
			if atyp, _ := e.Type.(*ast.ArrayType); atyp != nil && atyp.Len != nil {
				if ellip, _ := atyp.Len.(*ast.Ellipsis); ellip != nil && ellip.Elt == nil {
					// We have an "open" [...]T array type.
					// Create a new ArrayType with unknown length (-1)
					// and finish setting it up after analyzing the literal.
					typ = &Array{len: -1, elem: check.typ(atyp.Elt)}
					openArray = true
				}
			}
			if typ == nil {
				typ = check.typ(e.Type)
			}
		}
		if typ == nil {
			check.error(e.Pos(), "missing type in composite literal")
			goto Error
		}

		switch typ, _ := deref(typ); utyp := typ.Underlying().(type) {
		case *Struct:
			if len(e.Elts) == 0 {
				break
			}
			fields := utyp.fields
			if _, ok := e.Elts[0].(*ast.KeyValueExpr); ok {
				// all elements must have keys
				visited := make([]bool, len(fields))
				for _, e := range e.Elts {
					kv, _ := e.(*ast.KeyValueExpr)
					if kv == nil {
						check.error(e.Pos(), "mixture of field:value and value elements in struct literal")
						continue
					}
					key, _ := kv.Key.(*ast.Ident)
					if key == nil {
						check.errorf(kv.Pos(), "invalid field name %s in struct literal", kv.Key)
						continue
					}
					i := fieldIndex(utyp.fields, check.pkg, key.Name)
					if i < 0 {
						check.errorf(kv.Pos(), "unknown field %s in struct literal", key.Name)
						continue
					}
					fld := fields[i]
					check.recordUse(key, fld)
					// 0 <= i < len(fields)
					if visited[i] {
						check.errorf(kv.Pos(), "duplicate field name %s in struct literal", key.Name)
						continue
					}
					visited[i] = true
					check.expr(x, kv.Value)
					etyp := fld.typ
					if !check.assignment(x, etyp) {
						if x.mode != invalid {
							check.errorf(x.pos(), "cannot use %s as %s value in struct literal", x, etyp)
						}
						continue
					}
				}
			} else {
				// no element must have a key
				for i, e := range e.Elts {
					if kv, _ := e.(*ast.KeyValueExpr); kv != nil {
						check.error(kv.Pos(), "mixture of field:value and value elements in struct literal")
						continue
					}
					check.expr(x, e)
					if i >= len(fields) {
						check.error(x.pos(), "too many values in struct literal")
						break // cannot continue
					}
					// i < len(fields)
					etyp := fields[i].typ
					if !check.assignment(x, etyp) {
						if x.mode != invalid {
							check.errorf(x.pos(), "cannot use %s as %s value in struct literal", x, etyp)
						}
						continue
					}
				}
				if len(e.Elts) < len(fields) {
					check.error(e.Rbrace, "too few values in struct literal")
					// ok to continue
				}
			}

		case *Array:
			n := check.indexedElts(e.Elts, utyp.elem, utyp.len)
			// if we have an "open" [...]T array, set the length now that we know it
			if openArray {
				utyp.len = n
			}

		case *Slice:
			check.indexedElts(e.Elts, utyp.elem, -1)

		case *Map:
			visited := make(map[interface{}][]Type, len(e.Elts))
			for _, e := range e.Elts {
				kv, _ := e.(*ast.KeyValueExpr)
				if kv == nil {
					check.error(e.Pos(), "missing key in map literal")
					continue
				}
				check.expr(x, kv.Key)
				if !check.assignment(x, utyp.key) {
					if x.mode != invalid {
						check.errorf(x.pos(), "cannot use %s as %s key in map literal", x, utyp.key)
					}
					continue
				}
				if x.mode == constant {
					duplicate := false
					// if the key is of interface type, the type is also significant when checking for duplicates
					if _, ok := utyp.key.Underlying().(*Interface); ok {
						for _, vtyp := range visited[x.val] {
							if Identical(vtyp, x.typ) {
								duplicate = true
								break
							}
						}
						visited[x.val] = append(visited[x.val], x.typ)
					} else {
						_, duplicate = visited[x.val]
						visited[x.val] = nil
					}
					if duplicate {
						check.errorf(x.pos(), "duplicate key %s in map literal", x.val)
						continue
					}
				}
				check.exprWithHint(x, kv.Value, utyp.elem)
				if !check.assignment(x, utyp.elem) {
					if x.mode != invalid {
						check.errorf(x.pos(), "cannot use %s as %s value in map literal", x, utyp.elem)
					}
					continue
				}
			}

		default:
			check.errorf(e.Pos(), "invalid composite literal type %s", typ)
			goto Error
		}

		x.mode = value
		x.typ = typ

	case *ast.ParenExpr:
		kind := check.rawExpr(x, e.X, nil)
		x.expr = e
		return kind

	case *ast.SelectorExpr:
		check.selector(x, e)

	case *ast.IndexExpr:
		check.expr(x, e.X)
		if x.mode == invalid {
			goto Error
		}

		valid := false
		length := int64(-1) // valid if >= 0
		switch typ := x.typ.Underlying().(type) {
		case *Basic:
			if isString(typ) {
				valid = true
				if x.mode == constant {
					length = int64(len(exact.StringVal(x.val)))
				}
				// an indexed string always yields a byte value
				// (not a constant) even if the string and the
				// index are constant
				x.mode = value
				x.typ = UniverseByte // use 'byte' name
			}

		case *Array:
			valid = true
			length = typ.len
			if x.mode != variable {
				x.mode = value
			}
			x.typ = typ.elem

		case *Pointer:
			if typ, _ := typ.base.Underlying().(*Array); typ != nil {
				valid = true
				length = typ.len
				x.mode = variable
				x.typ = typ.elem
			}

		case *Slice:
			valid = true
			x.mode = variable
			x.typ = typ.elem

		case *Map:
			var key operand
			check.expr(&key, e.Index)
			if !check.assignment(&key, typ.key) {
				if key.mode != invalid {
					check.invalidOp(key.pos(), "cannot use %s as map index of type %s", &key, typ.key)
				}
				goto Error
			}
			x.mode = mapindex
			x.typ = typ.elem
			x.expr = e
			return expression
		}

		if !valid {
			check.invalidOp(x.pos(), "cannot index %s", x)
			goto Error
		}

		if e.Index == nil {
			check.invalidAST(e.Pos(), "missing index for %s", x)
			goto Error
		}

		check.index(e.Index, length)
		// ok to continue

	case *ast.SliceExpr:
		check.expr(x, e.X)
		if x.mode == invalid {
			goto Error
		}

		valid := false
		length := int64(-1) // valid if >= 0
		switch typ := x.typ.Underlying().(type) {
		case *Basic:
			if isString(typ) {
				if slice3(e) {
					check.invalidOp(x.pos(), "3-index slice of string")
					goto Error
				}
				valid = true
				if x.mode == constant {
					length = int64(len(exact.StringVal(x.val)))
				}
				// spec: "For untyped string operands the result
				// is a non-constant value of type string."
				if typ.kind == UntypedString {
					x.typ = Typ[String]
				}
			}

		case *Array:
			valid = true
			length = typ.len
			if x.mode != variable {
				check.invalidOp(x.pos(), "cannot slice %s (value not addressable)", x)
				goto Error
			}
			x.typ = &Slice{elem: typ.elem}

		case *Pointer:
			if typ, _ := typ.base.Underlying().(*Array); typ != nil {
				valid = true
				length = typ.len
				x.typ = &Slice{elem: typ.elem}
			}

		case *Slice:
			valid = true
			// x.typ doesn't change
		}

		if !valid {
			check.invalidOp(x.pos(), "cannot slice %s", x)
			goto Error
		}

		x.mode = value

		// spec: "Only the first index may be omitted; it defaults to 0."
		if slice3(e) && (e.High == nil || sliceMax(e) == nil) {
			check.error(e.Rbrack, "2nd and 3rd index required in 3-index slice")
			goto Error
		}

		// check indices
		var ind [3]int64
		for i, expr := range []ast.Expr{e.Low, e.High, sliceMax(e)} {
			x := int64(-1)
			switch {
			case expr != nil:
				// The "capacity" is only known statically for strings, arrays,
				// and pointers to arrays, and it is the same as the length for
				// those types.
				max := int64(-1)
				if length >= 0 {
					max = length + 1
				}
				if t, ok := check.index(expr, max); ok && t >= 0 {
					x = t
				}
			case i == 0:
				// default is 0 for the first index
				x = 0
			case length >= 0:
				// default is length (== capacity) otherwise
				x = length
			}
			ind[i] = x
		}

		// constant indices must be in range
		// (check.index already checks that existing indices >= 0)
	L:
		for i, x := range ind[:len(ind)-1] {
			if x > 0 {
				for _, y := range ind[i+1:] {
					if y >= 0 && x > y {
						check.errorf(e.Rbrack, "invalid slice indices: %d > %d", x, y)
						break L // only report one error, ok to continue
					}
				}
			}
		}

	case *ast.TypeAssertExpr:
		check.expr(x, e.X)
		if x.mode == invalid {
			goto Error
		}
		xtyp, _ := x.typ.Underlying().(*Interface)
		if xtyp == nil {
			check.invalidOp(x.pos(), "%s is not an interface", x)
			goto Error
		}
		// x.(type) expressions are handled explicitly in type switches
		if e.Type == nil {
			check.invalidAST(e.Pos(), "use of .(type) outside type switch")
			goto Error
		}
		T := check.typ(e.Type)
		if T == Typ[Invalid] {
			goto Error
		}
		check.typeAssertion(x.pos(), x, xtyp, T)
		x.mode = commaok
		x.typ = T

	case *ast.CallExpr:
		return check.call(x, e)

	case *ast.StarExpr:
		check.exprOrType(x, e.X)
		switch x.mode {
		case invalid:
			goto Error
		case typexpr:
			x.typ = &Pointer{base: x.typ}
		default:
			if typ, ok := x.typ.Underlying().(*Pointer); ok {
				x.mode = variable
				x.typ = typ.base
			} else {
				check.invalidOp(x.pos(), "cannot indirect %s", x)
				goto Error
			}
		}

	case *ast.UnaryExpr:
		check.expr(x, e.X)
		if x.mode == invalid {
			goto Error
		}
		check.unary(x, e.Op)
		if x.mode == invalid {
			goto Error
		}
		if e.Op == token.ARROW {
			x.expr = e
			return statement // receive operations may appear in statement context
		}

	case *ast.BinaryExpr:
		check.binary(x, e.X, e.Y, e.Op)
		if x.mode == invalid {
			goto Error
		}

	case *ast.KeyValueExpr:
		// key:value expressions are handled in composite literals
		check.invalidAST(e.Pos(), "no key:value expected")
		goto Error

	case *ast.ArrayType, *ast.StructType, *ast.FuncType,
		*ast.InterfaceType, *ast.MapType, *ast.ChanType:
		x.mode = typexpr
		x.typ = check.typ(e)
		// Note: rawExpr (caller of exprInternal) will call check.recordTypeAndValue
		// even though check.typ has already called it. This is fine as both
		// times the same expression and type are recorded. It is also not a
		// performance issue because we only reach here for composite literal
		// types, which are comparatively rare.

	default:
		panic(fmt.Sprintf("%s: unknown expression type %T", check.fset.Position(e.Pos()), e))
	}

	// everything went well
	x.expr = e
	return expression

Error:
	x.mode = invalid
	x.expr = e
	return statement // avoid follow-up errors
}
Esempio n. 24
0
// literalValue returns the value of the literal with the
// dynamic type tag appropriate for l.Type().
func literalValue(l *ssa.Literal) value {
	if l.IsNil() {
		return zero(l.Type()) // typed nil
	}

	// By destination type:
	switch t := l.Type().Underlying().(type) {
	case *types.Basic:
		switch t.Kind() {
		case types.Bool, types.UntypedBool:
			return exact.BoolVal(l.Value)
		case types.Int, types.UntypedInt:
			// Assume sizeof(int) is same on host and target.
			return int(l.Int64())
		case types.Int8:
			return int8(l.Int64())
		case types.Int16:
			return int16(l.Int64())
		case types.Int32, types.UntypedRune:
			return int32(l.Int64())
		case types.Int64:
			return l.Int64()
		case types.Uint:
			// Assume sizeof(uint) is same on host and target.
			return uint(l.Uint64())
		case types.Uint8:
			return uint8(l.Uint64())
		case types.Uint16:
			return uint16(l.Uint64())
		case types.Uint32:
			return uint32(l.Uint64())
		case types.Uint64:
			return l.Uint64()
		case types.Uintptr:
			// Assume sizeof(uintptr) is same on host and target.
			return uintptr(l.Uint64())
		case types.Float32:
			return float32(l.Float64())
		case types.Float64, types.UntypedFloat:
			return l.Float64()
		case types.Complex64:
			return complex64(l.Complex128())
		case types.Complex128, types.UntypedComplex:
			return l.Complex128()
		case types.String, types.UntypedString:
			if l.Value.Kind() == exact.String {
				return exact.StringVal(l.Value)
			}
			return string(rune(l.Int64()))
		case types.UnsafePointer:
			panic("unsafe.Pointer literal") // not possible
		case types.UntypedNil:
			// nil was handled above.
		}

	case *types.Slice:
		switch et := t.Elem().Underlying().(type) {
		case *types.Basic:
			switch et.Kind() {
			case types.Byte: // string -> []byte
				var v []value
				for _, b := range []byte(exact.StringVal(l.Value)) {
					v = append(v, b)
				}
				return v
			case types.Rune: // string -> []rune
				var v []value
				for _, r := range []rune(exact.StringVal(l.Value)) {
					v = append(v, r)
				}
				return v
			}
		}
	}

	panic(fmt.Sprintf("literalValue: Value.(type)=%T Type()=%s", l.Value, l.Type()))
}