cue/ast.go - cue - Git at Google

 // Copyright 2018 The CUE Authors
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 package cue

 import (
 	"fmt"
 	"strings"

 	"cuelang.org/go/cue/ast"
 	"cuelang.org/go/cue/build"
 	"cuelang.org/go/cue/literal"
 	"cuelang.org/go/cue/token"
 	"cuelang.org/go/internal"
 )

 // insertFile inserts the given file at the root of the instance.
 //
 // The contents will be merged (unified) with any pre-existing value. In this
 // case an error may be reported, but only if the merge failed at the top-level.
 // Other errors will be recorded at the respective values in the tree.
 //
 // There should be no unresolved identifiers in file, meaning the Node field
 // of all identifiers should be set to a non-nil value.
 func (inst *Instance) insertFile(f *ast.File) error {
 	// TODO: insert by converting to value first so that the trim command can
 	// also remove top-level fields.
 	// First process single file.
 	v := newVisitor(inst.index, inst.inst, inst.rootStruct, inst.scope)
 	v.astState.astMap[f] = inst.rootStruct
 	result := v.walk(f)
 	if isBottom(result) {
 		return result.(*bottom)
 	}

 	return nil
 }

 type astVisitor struct {
 	*astState
 	object *structLit

 	inSelector int
 }

 func (v *astVisitor) ctx() *context {
 	return v.astState.ctx
 }

 type astState struct {
 	ctx *context
 	*index
 	inst *build.Instance

 	litParser   *litParser
 	resolveRoot *structLit

 	// make unique per level to avoid reuse of structs being an issue.
 	astMap map[ast.Node]scope
 }

 func (s *astState) mapScope(n ast.Node) (m scope) {
 	if m = s.astMap[n]; m == nil {
 		m = newStruct(newNode(n))
 		s.astMap[n] = m
 	}
 	return m
 }

 func (s *astState) setScope(n ast.Node, v scope) {
 	if m, ok := s.astMap[n]; ok && m != v {
 		panic("already defined")
 	}
 	s.astMap[n] = v
 }

 func newVisitor(idx *index, inst *build.Instance, obj, resolveRoot *structLit) *astVisitor {
 	ctx := idx.newContext()
 	return newVisitorCtx(ctx, inst, obj, resolveRoot)
 }

 func newVisitorCtx(ctx *context, inst *build.Instance, obj, resolveRoot *structLit) *astVisitor {
 	v := &astVisitor{
 		object: obj,
 	}
 	v.astState = &astState{
 		ctx:         ctx,
 		index:       ctx.index,
 		inst:        inst,
 		litParser:   &litParser{ctx: ctx},
 		resolveRoot: resolveRoot,
 		astMap:      map[ast.Node]scope{},
 	}
 	return v
 }

 func (v *astVisitor) error(n ast.Node, args ...interface{}) value {
 	return v.mkErr(newNode(n), args...)
 }

 func (v *astVisitor) resolve(n *ast.Ident) value {
 	ctx := v.ctx()
 	label := v.label(n.Name, true)
 	if r := v.resolveRoot; r != nil {
 		for _, a := range r.arcs {
 			if a.feature == label {
 				return &selectorExpr{newExpr(n),
 					&nodeRef{baseValue: newExpr(n), node: r}, label}
 			}
 		}
 		if v.inSelector > 0 {
 			if p := getBuiltinShorthandPkg(ctx, n.Name); p != nil {
 				return &nodeRef{baseValue: newExpr(n), node: p}
 			}
 		}
 	}
 	return nil
 }

 func (v *astVisitor) loadImport(imp *ast.ImportSpec) evaluated {
 	ctx := v.ctx()
 	path, err := literal.Unquote(imp.Path.Value)
 	if err != nil {
 		return ctx.mkErr(newNode(imp), "illformed import spec")
 	}
 	// TODO: allow builtin *and* imported package. The result is a unified
 	// struct.
 	if p := getBuiltinPkg(ctx, path); p != nil {
 		return p
 	}
 	bimp := v.inst.LookupImport(path)
 	if bimp == nil {
 		return ctx.mkErr(newNode(imp), "package %q not found", path)
 	}
 	impInst := v.index.loadInstance(bimp)
 	return impInst.rootValue.evalPartial(ctx)
 }

 // We probably don't need to call Walk.s
 func (v *astVisitor) walk(astNode ast.Node) (value value) {
 	switch n := astNode.(type) {
 	case *ast.File:
 		obj := v.object
 		v1 := &astVisitor{
 			astState: v.astState,
 			object:   obj,
 		}
 		for _, e := range n.Decls {
 			switch x := e.(type) {
 			case *ast.EmitDecl:
 				if v1.object.emit == nil {
 					v1.object.emit = v1.walk(x.Expr)
 				} else {
 					v1.object.emit = mkBin(v.ctx(), token.NoPos, opUnify, v1.object.emit, v1.walk(x.Expr))
 				}
 			default:
 				v1.walk(e)
 			}
 		}
 		value = obj

 	case *ast.ImportDecl:
 		for _, s := range n.Specs {
 			v.walk(s)
 		}

 	case *ast.ImportSpec:
 		val := v.loadImport(n)
 		if !isBottom(val) {
 			v.setScope(n, val.(*structLit))
 		}

 	case *ast.StructLit:
 		obj := v.mapScope(n).(*structLit)
 		v1 := &astVisitor{
 			astState: v.astState,
 			object:   obj,
 		}
 		for _, e := range n.Elts {
 			switch x := e.(type) {
 			case *ast.EmitDecl:
 				// Only allowed at top-level.
 				v1.error(x, "emitting values is only allowed at top level")
 			case *ast.Field, *ast.Alias:
 				v1.walk(e)
 			case *ast.ComprehensionDecl:
 				v1.walk(x)
 			}
 		}
 		value = obj

 	case *ast.ComprehensionDecl:
 		yielder := &yield{baseValue: newExpr(n.Field.Value)}
 		fc := &fieldComprehension{
 			baseValue: newDecl(n),
 			clauses:   wrapClauses(v, yielder, n.Clauses),
 		}
 		field := n.Field
 		switch x := field.Label.(type) {
 		case *ast.Interpolation:
 			yielder.key = v.walk(x)
 			yielder.value = v.walk(field.Value)

 		case *ast.TemplateLabel:
 			f := v.label(x.Ident.Name, true)

 			sig := &params{}
 			sig.add(f, &basicType{newNode(field.Label), stringKind})
 			template := &lambdaExpr{newExpr(field.Value), sig, nil}

 			v.setScope(field, template)
 			template.value = v.walk(field.Value)
 			yielder.value = template
 			fc.isTemplate = true

 		case *ast.BasicLit, *ast.Ident:
 			name, ok := ast.LabelName(x)
 			if !ok {
 				return v.error(x, "invalid field name: %v", x)
 			}

 			// TODO: if the clauses do not contain a guard, we know that this
 			// field will always be added and we can move the comprehension one
 			// level down. This, in turn, has the advantage that it is more
 			// likely that the cross-reference limitation for field
 			// comprehensions is not violated. To ensure compatibility between
 			// implementations, though, we should relax the spec as well.
 			// The cross-reference rule is simple and this relaxation seems a
 			// bit more complex.

 			// TODO: for now we can also consider making this an error if
 			// the list of clauses does not contain if and make a suggestion
 			// to rewrite it.

 			if name != "" {
 				yielder.key = &stringLit{newNode(x), name}
 				yielder.value = v.walk(field.Value)
 			}

 		default:
 			panic("cue: unknown label type")
 		}
 		// yielder.key = v.walk(n.Field.Label)
 		// yielder.value = v.walk(n.Field.Value)
 		v.object.comprehensions = append(v.object.comprehensions, fc)

 	case *ast.Field:
 		opt := n.Optional != token.NoPos
 		switch x := n.Label.(type) {
 		case *ast.Interpolation:
 			yielder := &yield{baseValue: newNode(x)}
 			fc := &fieldComprehension{
 				baseValue: newDecl(n),
 				clauses:   yielder,
 			}
 			yielder.key = v.walk(x)
 			yielder.value = v.walk(n.Value)
 			yielder.opt = opt
 			v.object.comprehensions = append(v.object.comprehensions, fc)

 		case *ast.TemplateLabel:
 			f := v.label(x.Ident.Name, true)

 			sig := &params{}
 			sig.add(f, &basicType{newNode(n.Label), stringKind})
 			template := &lambdaExpr{newExpr(n.Value), sig, nil}

 			v.setScope(n, template)
 			template.value = v.walk(n.Value)

 			if v.object.template == nil {
 				v.object.template = template
 			} else {
 				v.object.template = mkBin(v.ctx(), token.NoPos, opUnify, v.object.template, template)
 			}

 		case *ast.BasicLit, *ast.Ident:
 			if internal.DropOptional && opt {
 				break
 			}
 			attrs, err := createAttrs(v.ctx(), newNode(n), n.Attrs)
 			if err != nil {
 				return err
 			}
 			f, ok := v.nodeLabel(x)
 			if !ok {
 				return v.error(n.Label, "invalid field name: %v", n.Label)
 			}
 			if f != 0 {
 				v.object.insertValue(v.ctx(), f, opt, v.walk(n.Value), attrs)
 			}

 		default:
 			panic("cue: unknown label type")
 		}

 	case *ast.Alias:
 		// parsed verbatim at reference.

 	case *ast.ListComprehension:
 		yielder := &yield{baseValue: newExpr(n.Expr)}
 		lc := &listComprehension{
 			newExpr(n),
 			wrapClauses(v, yielder, n.Clauses),
 		}
 		// we don't support key for lists (yet?)
 		yielder.value = v.walk(n.Expr)
 		return lc

 	// Expressions
 	case *ast.Ident:
 		if n.Node == nil {
 			if value = v.resolve(n); value != nil {
 				break
 			}

 			switch n.Name {
 			case "_":
 				return &top{newExpr(n)}
 			case "string":
 				return &basicType{newExpr(n), stringKind}
 			case "bytes":
 				return &basicType{newExpr(n), bytesKind}
 			case "bool":
 				return &basicType{newExpr(n), boolKind}
 			case "int":
 				return &basicType{newExpr(n), intKind}
 			case "float":
 				return &basicType{newExpr(n), floatKind}
 			case "number":
 				return &basicType{newExpr(n), numKind}
 			case "duration":
 				return &basicType{newExpr(n), durationKind}

 			case "len":
 				return lenBuiltin
 			}
 			if r, ok := predefinedRanges[n.Name]; ok {
 				return r
 			}

 			value = v.error(n, "reference %q not found", n.Name)
 			break
 		}

 		if a, ok := n.Node.(*ast.Alias); ok {
 			value = v.walk(a.Expr)
 			break
 		}

 		label := v.label(n.Name, true)
 		if n.Scope != nil {
 			n2 := v.mapScope(n.Scope)
 			value = &nodeRef{baseValue: newExpr(n), node: n2}
 			value = &selectorExpr{newExpr(n), value, label}
 		} else {
 			n2 := v.mapScope(n.Node)
 			value = &nodeRef{baseValue: newExpr(n), node: n2}
 		}

 	case *ast.BottomLit:
 		value = v.error(n, "from source")

 	case *ast.BadDecl:
 		// nothing to do

 	case *ast.BadExpr:
 		value = v.error(n, "invalid expression")

 	case *ast.BasicLit:
 		value = v.litParser.parse(n)

 	case *ast.Interpolation:
 		if len(n.Elts) == 0 {
 			return v.error(n, "invalid interpolation")
 		}
 		first, ok1 := n.Elts[0].(*ast.BasicLit)
 		last, ok2 := n.Elts[len(n.Elts)-1].(*ast.BasicLit)
 		if !ok1 || !ok2 {
 			return v.error(n, "invalid interpolation")
 		}
 		if len(n.Elts) == 1 {
 			value = v.walk(n.Elts[0])
 			break
 		}
 		lit := &interpolation{baseValue: newExpr(n), k: stringKind}
 		value = lit
 		info, prefixLen, _, err := literal.ParseQuotes(first.Value, last.Value)
 		if err != nil {
 			return v.error(n, "invalid interpolation: %v", err)
 		}
 		prefix := ""
 		for i := 0; i < len(n.Elts); i += 2 {
 			l, ok := n.Elts[i].(*ast.BasicLit)
 			if !ok {
 				return v.error(n, "invalid interpolation")
 			}
 			s := l.Value
 			if !strings.HasPrefix(s, prefix) {
 				return v.error(l, "invalid interpolation: unmatched ')'")
 			}
 			s = l.Value[prefixLen:]
 			x := parseString(v.ctx(), l, info, s)
 			lit.parts = append(lit.parts, x)
 			if i+1 < len(n.Elts) {
 				lit.parts = append(lit.parts, v.walk(n.Elts[i+1]))
 			}
 			prefix = ")"
 			prefixLen = 1
 		}

 	case *ast.ListLit:
 		list := &list{baseValue: newExpr(n)}
 		for _, e := range n.Elts {
 			list.a = append(list.a, v.walk(e))
 		}
 		list.initLit()
 		if n.Ellipsis != token.NoPos || n.Type != nil {
 			list.len = &bound{list.baseValue, opGeq, list.len}
 			if n.Type != nil {
 				list.typ = v.walk(n.Type)
 			}
 		}
 		value = list

 	case *ast.ParenExpr:
 		value = v.walk(n.X)

 	case *ast.SelectorExpr:
 		v.inSelector++
 		value = &selectorExpr{
 			newExpr(n),
 			v.walk(n.X),
 			v.label(n.Sel.Name, true),
 		}
 		v.inSelector--

 	case *ast.IndexExpr:
 		value = &indexExpr{newExpr(n), v.walk(n.X), v.walk(n.Index)}

 	case *ast.SliceExpr:
 		slice := &sliceExpr{baseValue: newExpr(n), x: v.walk(n.X)}
 		if n.Low != nil {
 			slice.lo = v.walk(n.Low)
 		}
 		if n.High != nil {
 			slice.hi = v.walk(n.High)
 		}
 		value = slice

 	case *ast.CallExpr:
 		call := &callExpr{baseValue: newExpr(n), x: v.walk(n.Fun)}
 		for _, a := range n.Args {
 			call.args = append(call.args, v.walk(a))
 		}
 		value = call

 	case *ast.UnaryExpr:
 		switch n.Op {
 		case token.NOT, token.ADD, token.SUB:
 			value = &unaryExpr{
 				newExpr(n),
 				tokenMap[n.Op],
 				v.walk(n.X),
 			}
 		case token.GEQ, token.GTR, token.LSS, token.LEQ,
 			token.NEQ, token.MAT, token.NMAT:
 			value = &bound{
 				newExpr(n),
 				tokenMap[n.Op],
 				v.walk(n.X),
 			}

 		case token.MUL:
 			return v.error(n, "preference mark not allowed at this position")
 		default:
 			return v.error(n, "unsupported unary operator %q", n.Op)
 		}

 	case *ast.BinaryExpr:
 		switch n.Op {
 		case token.OR:
 			d := &disjunction{baseValue: newExpr(n)}
 			v.addDisjunctionElem(d, n.X, false)
 			v.addDisjunctionElem(d, n.Y, false)
 			value = d

 		default:
 			value = &binaryExpr{
 				newExpr(n),
 				tokenMap[n.Op], // op
 				v.walk(n.X),    // left
 				v.walk(n.Y),    // right
 			}
 		}

 	// nothing to do
 	// case *syntax.EmitDecl:
 	default:
 		// TODO: unhandled node.
 		// value = ctx.mkErr(n, "unknown node type %T", n)
 		panic(fmt.Sprintf("unimplemented %T", n))

 	}
 	return value
 }

 func (v *astVisitor) addDisjunctionElem(d *disjunction, n ast.Node, mark bool) {
 	switch x := n.(type) {
 	case *ast.BinaryExpr:
 		if x.Op == token.OR {
 			v.addDisjunctionElem(d, x.X, mark)
 			v.addDisjunctionElem(d, x.Y, mark)
 			return
 		}
 	case *ast.UnaryExpr:
 		if x.Op == token.MUL {
 			mark = true
 			n = x.X
 		}
 	}
 	d.values = append(d.values, dValue{v.walk(n), mark})
 }

 func wrapClauses(v *astVisitor, y yielder, clauses []ast.Clause) yielder {
 	for _, c := range clauses {
 		if n, ok := c.(*ast.ForClause); ok {
 			params := &params{}
 			fn := &lambdaExpr{newExpr(n.Source), params, nil}
 			v.setScope(n, fn)
 		}
 	}
 	for i := len(clauses) - 1; i >= 0; i-- {
 		switch n := clauses[i].(type) {
 		case *ast.ForClause:
 			fn := v.mapScope(n).(*lambdaExpr)
 			fn.value = y

 			key := "_"
 			if n.Key != nil {
 				key = n.Key.Name
 			}
 			f := v.label(key, true)
 			fn.add(f, &basicType{newExpr(n.Key), stringKind | intKind})

 			f = v.label(n.Value.Name, true)
 			fn.add(f, &top{})

 			y = &feed{newExpr(n.Source), v.walk(n.Source), fn}

 		case *ast.IfClause:
 			y = &guard{newExpr(n.Condition), v.walk(n.Condition), y}
 		}
 	}
 	return y
 }
	// Copyright 2018 The CUE Authors
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	package cue

	import (
	"fmt"
	"strings"

	"cuelang.org/go/cue/ast"
	"cuelang.org/go/cue/build"
	"cuelang.org/go/cue/literal"
	"cuelang.org/go/cue/token"
	"cuelang.org/go/internal"
	)

	// insertFile inserts the given file at the root of the instance.
	//
	// The contents will be merged (unified) with any pre-existing value. In this
	// case an error may be reported, but only if the merge failed at the top-level.
	// Other errors will be recorded at the respective values in the tree.
	//
	// There should be no unresolved identifiers in file, meaning the Node field
	// of all identifiers should be set to a non-nil value.
	func (inst Instance) insertFile(f ast.File) error {
	// TODO: insert by converting to value first so that the trim command can
	// also remove top-level fields.
	// First process single file.
	v := newVisitor(inst.index, inst.inst, inst.rootStruct, inst.scope)
	v.astState.astMap[f] = inst.rootStruct
	result := v.walk(f)
	if isBottom(result) {
	return result.(*bottom)
	}

	return nil
	}

	type astVisitor struct {
	*astState
	object *structLit

	inSelector int
	}

	func (v astVisitor) ctx() context {
	return v.astState.ctx
	}

	type astState struct {
	ctx *context
	*index
	inst *build.Instance

	litParser *litParser
	resolveRoot *structLit

	// make unique per level to avoid reuse of structs being an issue.
	astMap map[ast.Node]scope
	}

	func (s *astState) mapScope(n ast.Node) (m scope) {
	if m = s.astMap[n]; m == nil {
	m = newStruct(newNode(n))
	s.astMap[n] = m
	}
	return m
	}

	func (s *astState) setScope(n ast.Node, v scope) {
	if m, ok := s.astMap[n]; ok && m != v {
	panic("already defined")
	}
	s.astMap[n] = v
	}

	func newVisitor(idx index, inst build.Instance, obj, resolveRoot structLit) astVisitor {
	ctx := idx.newContext()
	return newVisitorCtx(ctx, inst, obj, resolveRoot)
	}

	func newVisitorCtx(ctx context, inst build.Instance, obj, resolveRoot structLit) astVisitor {
	v := &astVisitor{
	object: obj,
	}
	v.astState = &astState{
	ctx: ctx,
	index: ctx.index,
	inst: inst,
	litParser: &litParser{ctx: ctx},
	resolveRoot: resolveRoot,
	astMap: map[ast.Node]scope{},
	}
	return v
	}

	func (v *astVisitor) error(n ast.Node, args ...interface{}) value {
	return v.mkErr(newNode(n), args...)
	}

	func (v astVisitor) resolve(n ast.Ident) value {
	ctx := v.ctx()
	label := v.label(n.Name, true)
	if r := v.resolveRoot; r != nil {
	for _, a := range r.arcs {
	if a.feature == label {
	return &selectorExpr{newExpr(n),
	&nodeRef{baseValue: newExpr(n), node: r}, label}
	}
	}
	if v.inSelector > 0 {
	if p := getBuiltinShorthandPkg(ctx, n.Name); p != nil {
	return &nodeRef{baseValue: newExpr(n), node: p}
	}
	}
	}
	return nil
	}

	func (v astVisitor) loadImport(imp ast.ImportSpec) evaluated {
	ctx := v.ctx()
	path, err := literal.Unquote(imp.Path.Value)
	if err != nil {
	return ctx.mkErr(newNode(imp), "illformed import spec")
	}
	// TODO: allow builtin and imported package. The result is a unified
	// struct.
	if p := getBuiltinPkg(ctx, path); p != nil {
	return p
	}
	bimp := v.inst.LookupImport(path)
	if bimp == nil {
	return ctx.mkErr(newNode(imp), "package %q not found", path)
	}
	impInst := v.index.loadInstance(bimp)
	return impInst.rootValue.evalPartial(ctx)
	}

	// We probably don't need to call Walk.s
	func (v *astVisitor) walk(astNode ast.Node) (value value) {
	switch n := astNode.(type) {
	case *ast.File:
	obj := v.object
	v1 := &astVisitor{
	astState: v.astState,
	object: obj,
	}
	for _, e := range n.Decls {
	switch x := e.(type) {
	case *ast.EmitDecl:
	if v1.object.emit == nil {
	v1.object.emit = v1.walk(x.Expr)
	} else {
	v1.object.emit = mkBin(v.ctx(), token.NoPos, opUnify, v1.object.emit, v1.walk(x.Expr))
	}
	default:
	v1.walk(e)
	}
	}
	value = obj

	case *ast.ImportDecl:
	for _, s := range n.Specs {
	v.walk(s)
	}

	case *ast.ImportSpec:
	val := v.loadImport(n)
	if !isBottom(val) {
	v.setScope(n, val.(*structLit))
	}

	case *ast.StructLit:
	obj := v.mapScope(n).(*structLit)
	v1 := &astVisitor{
	astState: v.astState,
	object: obj,
	}
	for _, e := range n.Elts {
	switch x := e.(type) {
	case *ast.EmitDecl:
	// Only allowed at top-level.
	v1.error(x, "emitting values is only allowed at top level")
	case ast.Field, ast.Alias:
	v1.walk(e)
	case *ast.ComprehensionDecl:
	v1.walk(x)
	}
	}
	value = obj

	case *ast.ComprehensionDecl:
	yielder := &yield{baseValue: newExpr(n.Field.Value)}
	fc := &fieldComprehension{
	baseValue: newDecl(n),
	clauses: wrapClauses(v, yielder, n.Clauses),
	}
	field := n.Field
	switch x := field.Label.(type) {
	case *ast.Interpolation:
	yielder.key = v.walk(x)
	yielder.value = v.walk(field.Value)

	case *ast.TemplateLabel:
	f := v.label(x.Ident.Name, true)

	sig := &params{}
	sig.add(f, &basicType{newNode(field.Label), stringKind})
	template := &lambdaExpr{newExpr(field.Value), sig, nil}

	v.setScope(field, template)
	template.value = v.walk(field.Value)
	yielder.value = template
	fc.isTemplate = true

	case ast.BasicLit, ast.Ident:
	name, ok := ast.LabelName(x)
	if !ok {
	return v.error(x, "invalid field name: %v", x)
	}

	// TODO: if the clauses do not contain a guard, we know that this
	// field will always be added and we can move the comprehension one
	// level down. This, in turn, has the advantage that it is more
	// likely that the cross-reference limitation for field
	// comprehensions is not violated. To ensure compatibility between
	// implementations, though, we should relax the spec as well.
	// The cross-reference rule is simple and this relaxation seems a
	// bit more complex.

	// TODO: for now we can also consider making this an error if
	// the list of clauses does not contain if and make a suggestion
	// to rewrite it.

	if name != "" {
	yielder.key = &stringLit{newNode(x), name}
	yielder.value = v.walk(field.Value)
	}

	default:
	panic("cue: unknown label type")
	}
	// yielder.key = v.walk(n.Field.Label)
	// yielder.value = v.walk(n.Field.Value)
	v.object.comprehensions = append(v.object.comprehensions, fc)

	case *ast.Field:
	opt := n.Optional != token.NoPos
	switch x := n.Label.(type) {
	case *ast.Interpolation:
	yielder := &yield{baseValue: newNode(x)}
	fc := &fieldComprehension{
	baseValue: newDecl(n),
	clauses: yielder,
	}
	yielder.key = v.walk(x)
	yielder.value = v.walk(n.Value)
	yielder.opt = opt
	v.object.comprehensions = append(v.object.comprehensions, fc)

	case *ast.TemplateLabel:
	f := v.label(x.Ident.Name, true)

	sig := &params{}
	sig.add(f, &basicType{newNode(n.Label), stringKind})
	template := &lambdaExpr{newExpr(n.Value), sig, nil}

	v.setScope(n, template)
	template.value = v.walk(n.Value)

	if v.object.template == nil {
	v.object.template = template
	} else {
	v.object.template = mkBin(v.ctx(), token.NoPos, opUnify, v.object.template, template)
	}

	case ast.BasicLit, ast.Ident:
	if internal.DropOptional && opt {
	break
	}
	attrs, err := createAttrs(v.ctx(), newNode(n), n.Attrs)
	if err != nil {
	return err
	}
	f, ok := v.nodeLabel(x)
	if !ok {
	return v.error(n.Label, "invalid field name: %v", n.Label)
	}
	if f != 0 {
	v.object.insertValue(v.ctx(), f, opt, v.walk(n.Value), attrs)
	}

	default:
	panic("cue: unknown label type")
	}

	case *ast.Alias:
	// parsed verbatim at reference.

	case *ast.ListComprehension:
	yielder := &yield{baseValue: newExpr(n.Expr)}
	lc := &listComprehension{
	newExpr(n),
	wrapClauses(v, yielder, n.Clauses),
	}
	// we don't support key for lists (yet?)
	yielder.value = v.walk(n.Expr)
	return lc

	// Expressions
	case *ast.Ident:
	if n.Node == nil {
	if value = v.resolve(n); value != nil {
	break
	}

	switch n.Name {
	case "_":
	return &top{newExpr(n)}
	case "string":
	return &basicType{newExpr(n), stringKind}
	case "bytes":
	return &basicType{newExpr(n), bytesKind}
	case "bool":
	return &basicType{newExpr(n), boolKind}
	case "int":
	return &basicType{newExpr(n), intKind}
	case "float":
	return &basicType{newExpr(n), floatKind}
	case "number":
	return &basicType{newExpr(n), numKind}
	case "duration":
	return &basicType{newExpr(n), durationKind}

	case "len":
	return lenBuiltin
	}
	if r, ok := predefinedRanges[n.Name]; ok {
	return r
	}

	value = v.error(n, "reference %q not found", n.Name)
	break
	}

	if a, ok := n.Node.(*ast.Alias); ok {
	value = v.walk(a.Expr)
	break
	}

	label := v.label(n.Name, true)
	if n.Scope != nil {
	n2 := v.mapScope(n.Scope)
	value = &nodeRef{baseValue: newExpr(n), node: n2}
	value = &selectorExpr{newExpr(n), value, label}
	} else {
	n2 := v.mapScope(n.Node)
	value = &nodeRef{baseValue: newExpr(n), node: n2}
	}

	case *ast.BottomLit:
	value = v.error(n, "from source")

	case *ast.BadDecl:
	// nothing to do

	case *ast.BadExpr:
	value = v.error(n, "invalid expression")

	case *ast.BasicLit:
	value = v.litParser.parse(n)

	case *ast.Interpolation:
	if len(n.Elts) == 0 {
	return v.error(n, "invalid interpolation")
	}
	first, ok1 := n.Elts[0].(*ast.BasicLit)
	last, ok2 := n.Elts[len(n.Elts)-1].(*ast.BasicLit)
	if !ok1 \|\| !ok2 {
	return v.error(n, "invalid interpolation")
	}
	if len(n.Elts) == 1 {
	value = v.walk(n.Elts[0])
	break
	}
	lit := &interpolation{baseValue: newExpr(n), k: stringKind}
	value = lit
	info, prefixLen, _, err := literal.ParseQuotes(first.Value, last.Value)
	if err != nil {
	return v.error(n, "invalid interpolation: %v", err)
	}
	prefix := ""
	for i := 0; i < len(n.Elts); i += 2 {
	l, ok := n.Elts[i].(*ast.BasicLit)
	if !ok {
	return v.error(n, "invalid interpolation")
	}
	s := l.Value
	if !strings.HasPrefix(s, prefix) {
	return v.error(l, "invalid interpolation: unmatched ')'")
	}
	s = l.Value[prefixLen:]
	x := parseString(v.ctx(), l, info, s)
	lit.parts = append(lit.parts, x)
	if i+1 < len(n.Elts) {
	lit.parts = append(lit.parts, v.walk(n.Elts[i+1]))
	}
	prefix = ")"
	prefixLen = 1
	}

	case *ast.ListLit:
	list := &list{baseValue: newExpr(n)}
	for _, e := range n.Elts {
	list.a = append(list.a, v.walk(e))
	}
	list.initLit()
	if n.Ellipsis != token.NoPos \|\| n.Type != nil {
	list.len = &bound{list.baseValue, opGeq, list.len}
	if n.Type != nil {
	list.typ = v.walk(n.Type)
	}
	}
	value = list

	case *ast.ParenExpr:
	value = v.walk(n.X)

	case *ast.SelectorExpr:
	v.inSelector++
	value = &selectorExpr{
	newExpr(n),
	v.walk(n.X),
	v.label(n.Sel.Name, true),
	}
	v.inSelector--

	case *ast.IndexExpr:
	value = &indexExpr{newExpr(n), v.walk(n.X), v.walk(n.Index)}

	case *ast.SliceExpr:
	slice := &sliceExpr{baseValue: newExpr(n), x: v.walk(n.X)}
	if n.Low != nil {
	slice.lo = v.walk(n.Low)
	}
	if n.High != nil {
	slice.hi = v.walk(n.High)
	}
	value = slice

	case *ast.CallExpr:
	call := &callExpr{baseValue: newExpr(n), x: v.walk(n.Fun)}
	for _, a := range n.Args {
	call.args = append(call.args, v.walk(a))
	}
	value = call

	case *ast.UnaryExpr:
	switch n.Op {
	case token.NOT, token.ADD, token.SUB:
	value = &unaryExpr{
	newExpr(n),
	tokenMap[n.Op],
	v.walk(n.X),
	}
	case token.GEQ, token.GTR, token.LSS, token.LEQ,
	token.NEQ, token.MAT, token.NMAT:
	value = &bound{
	newExpr(n),
	tokenMap[n.Op],
	v.walk(n.X),
	}

	case token.MUL:
	return v.error(n, "preference mark not allowed at this position")
	default:
	return v.error(n, "unsupported unary operator %q", n.Op)
	}

	case *ast.BinaryExpr:
	switch n.Op {
	case token.OR:
	d := &disjunction{baseValue: newExpr(n)}
	v.addDisjunctionElem(d, n.X, false)
	v.addDisjunctionElem(d, n.Y, false)
	value = d

	default:
	value = &binaryExpr{
	newExpr(n),
	tokenMap[n.Op], // op
	v.walk(n.X), // left
	v.walk(n.Y), // right
	}
	}

	// nothing to do
	// case *syntax.EmitDecl:
	default:
	// TODO: unhandled node.
	// value = ctx.mkErr(n, "unknown node type %T", n)
	panic(fmt.Sprintf("unimplemented %T", n))

	}
	return value
	}

	func (v astVisitor) addDisjunctionElem(d disjunction, n ast.Node, mark bool) {
	switch x := n.(type) {
	case *ast.BinaryExpr:
	if x.Op == token.OR {
	v.addDisjunctionElem(d, x.X, mark)
	v.addDisjunctionElem(d, x.Y, mark)
	return
	}
	case *ast.UnaryExpr:
	if x.Op == token.MUL {
	mark = true
	n = x.X
	}
	}
	d.values = append(d.values, dValue{v.walk(n), mark})
	}

	func wrapClauses(v *astVisitor, y yielder, clauses []ast.Clause) yielder {
	for _, c := range clauses {
	if n, ok := c.(*ast.ForClause); ok {
	params := &params{}
	fn := &lambdaExpr{newExpr(n.Source), params, nil}
	v.setScope(n, fn)
	}
	}
	for i := len(clauses) - 1; i >= 0; i-- {
	switch n := clauses[i].(type) {
	case *ast.ForClause:
	fn := v.mapScope(n).(*lambdaExpr)
	fn.value = y

	key := "_"
	if n.Key != nil {
	key = n.Key.Name
	}
	f := v.label(key, true)
	fn.add(f, &basicType{newExpr(n.Key), stringKind \| intKind})

	f = v.label(n.Value.Name, true)
	fn.add(f, &top{})

	y = &feed{newExpr(n.Source), v.walk(n.Source), fn}

	case *ast.IfClause:
	y = &guard{newExpr(n.Condition), v.walk(n.Condition), y}
	}
	}
	return y
	}