mk2rbc/expr.go - platform/build/soong - Git at Google

 // Copyright 2021 Google LLC
 //
 // 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 mk2rbc

 import (
 	"fmt"
 	"strconv"
 	"strings"

 	mkparser "android/soong/androidmk/parser"
 )

 // Represents an expression in the Starlark code. An expression has
 // a type, and it can be evaluated.
 type starlarkExpr interface {
 	starlarkNode
 	typ() starlarkType
 	// Try to substitute variable values. Return substitution result
 	// and whether it is the same as the original expression.
 	eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool)
 	// Emit the code to copy the expression, otherwise we will end up
 	// with source and target pointing to the same list.
 	emitListVarCopy(gctx *generationContext)
 }

 func maybeString(expr starlarkExpr) (string, bool) {
 	if x, ok := expr.(*stringLiteralExpr); ok {
 		return x.literal, true
 	}
 	return "", false
 }

 type stringLiteralExpr struct {
 	literal string
 }

 func (s *stringLiteralExpr) eval(_ map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	res = s
 	same = true
 	return
 }

 func (s *stringLiteralExpr) emit(gctx *generationContext) {
 	gctx.writef("%q", s.literal)
 }

 func (_ *stringLiteralExpr) typ() starlarkType {
 	return starlarkTypeString
 }

 func (s *stringLiteralExpr) emitListVarCopy(gctx *generationContext) {
 	s.emit(gctx)
 }

 // Integer literal
 type intLiteralExpr struct {
 	literal int
 }

 func (s *intLiteralExpr) eval(_ map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	res = s
 	same = true
 	return
 }

 func (s *intLiteralExpr) emit(gctx *generationContext) {
 	gctx.writef("%d", s.literal)
 }

 func (_ *intLiteralExpr) typ() starlarkType {
 	return starlarkTypeInt
 }

 func (s *intLiteralExpr) emitListVarCopy(gctx *generationContext) {
 	s.emit(gctx)
 }

 // interpolateExpr represents Starlark's interpolation operator <string> % list
 // we break <string> into a list of chunks, i.e., "first%second%third" % (X, Y)
 // will have chunks = ["first", "second", "third"] and args = [X, Y]
 type interpolateExpr struct {
 	chunks []string // string chunks, separated by '%'
 	args   []starlarkExpr
 }

 func (xi *interpolateExpr) emit(gctx *generationContext) {
 	if len(xi.chunks) != len(xi.args)+1 {
 		panic(fmt.Errorf("malformed interpolateExpr: #chunks(%d) != #args(%d)+1",
 			len(xi.chunks), len(xi.args)))
 	}
 	// Generate format as join of chunks, but first escape '%' in them
 	format := strings.ReplaceAll(xi.chunks[0], "%", "%%")
 	for _, chunk := range xi.chunks[1:] {
 		format += "%s" + strings.ReplaceAll(chunk, "%", "%%")
 	}
 	gctx.writef("%q %% ", format)
 	emitarg := func(arg starlarkExpr) {
 		if arg.typ() == starlarkTypeList {
 			gctx.write(`" ".join(`)
 			arg.emit(gctx)
 			gctx.write(`)`)
 		} else {
 			arg.emit(gctx)
 		}
 	}
 	if len(xi.args) == 1 {
 		emitarg(xi.args[0])
 	} else {
 		sep := "("
 		for _, arg := range xi.args {
 			gctx.write(sep)
 			emitarg(arg)
 			sep = ", "
 		}
 		gctx.write(")")
 	}
 }

 func (xi *interpolateExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	same = true
 	newChunks := []string{xi.chunks[0]}
 	var newArgs []starlarkExpr
 	for i, arg := range xi.args {
 		newArg, sameArg := arg.eval(valueMap)
 		same = same && sameArg
 		switch x := newArg.(type) {
 		case *stringLiteralExpr:
 			newChunks[len(newChunks)-1] += x.literal + xi.chunks[i+1]
 			same = false
 			continue
 		case *intLiteralExpr:
 			newChunks[len(newChunks)-1] += strconv.Itoa(x.literal) + xi.chunks[i+1]
 			same = false
 			continue
 		default:
 			newChunks = append(newChunks, xi.chunks[i+1])
 			newArgs = append(newArgs, newArg)
 		}
 	}
 	if same {
 		res = xi
 	} else if len(newChunks) == 1 {
 		res = &stringLiteralExpr{newChunks[0]}
 	} else {
 		res = &interpolateExpr{chunks: newChunks, args: newArgs}
 	}
 	return
 }

 func (_ *interpolateExpr) typ() starlarkType {
 	return starlarkTypeString
 }

 func (xi *interpolateExpr) emitListVarCopy(gctx *generationContext) {
 	xi.emit(gctx)
 }

 type variableRefExpr struct {
 	ref       variable
 	isDefined bool
 }

 func (v *variableRefExpr) eval(map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	predefined, ok := v.ref.(*predefinedVariable)
 	if same = !ok; same {
 		res = v
 	} else {
 		res = predefined.value
 	}
 	return
 }

 func (v *variableRefExpr) emit(gctx *generationContext) {
 	v.ref.emitGet(gctx, v.isDefined)
 }

 func (v *variableRefExpr) typ() starlarkType {
 	return v.ref.valueType()
 }

 func (v *variableRefExpr) emitListVarCopy(gctx *generationContext) {
 	v.emit(gctx)
 	if v.typ() == starlarkTypeList {
 		gctx.write("[:]") // this will copy the list
 	}
 }

 type notExpr struct {
 	expr starlarkExpr
 }

 func (n *notExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	if x, same := n.expr.eval(valueMap); same {
 		res = n
 	} else {
 		res = &notExpr{expr: x}
 	}
 	return
 }

 func (n *notExpr) emit(ctx *generationContext) {
 	ctx.write("not ")
 	n.expr.emit(ctx)
 }

 func (_ *notExpr) typ() starlarkType {
 	return starlarkTypeBool
 }

 func (n *notExpr) emitListVarCopy(gctx *generationContext) {
 	n.emit(gctx)
 }

 type eqExpr struct {
 	left, right starlarkExpr
 	isEq        bool // if false, it's !=
 }

 func (eq *eqExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	xLeft, sameLeft := eq.left.eval(valueMap)
 	xRight, sameRight := eq.right.eval(valueMap)
 	if same = sameLeft && sameRight; same {
 		res = eq
 	} else {
 		res = &eqExpr{left: xLeft, right: xRight, isEq: eq.isEq}
 	}
 	return
 }

 func (eq *eqExpr) emit(gctx *generationContext) {
 	emitSimple := func(expr starlarkExpr) {
 		if eq.isEq {
 			gctx.write("not ")
 		}
 		expr.emit(gctx)
 	}
 	// Are we checking that a variable is empty?
 	if isEmptyString(eq.left) {
 		emitSimple(eq.right)
 		return
 	} else if isEmptyString(eq.right) {
 		emitSimple(eq.left)
 		return

 	}
 	// General case
 	eq.left.emit(gctx)
 	if eq.isEq {
 		gctx.write(" == ")
 	} else {
 		gctx.write(" != ")
 	}
 	eq.right.emit(gctx)
 }

 func (_ *eqExpr) typ() starlarkType {
 	return starlarkTypeBool
 }

 func (eq *eqExpr) emitListVarCopy(gctx *generationContext) {
 	eq.emit(gctx)
 }

 // variableDefinedExpr corresponds to Make's ifdef VAR
 type variableDefinedExpr struct {
 	v variable
 }

 func (v *variableDefinedExpr) eval(_ map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	res = v
 	same = true
 	return

 }

 func (v *variableDefinedExpr) emit(gctx *generationContext) {
 	if v.v != nil {
 		v.v.emitDefined(gctx)
 		return
 	}
 	gctx.writef("%s(%q)", cfnWarning, "TODO(VAR)")
 }

 func (_ *variableDefinedExpr) typ() starlarkType {
 	return starlarkTypeBool
 }

 func (v *variableDefinedExpr) emitListVarCopy(gctx *generationContext) {
 	v.emit(gctx)
 }

 type listExpr struct {
 	items []starlarkExpr
 }

 func (l *listExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	newItems := make([]starlarkExpr, len(l.items))
 	same = true
 	for i, item := range l.items {
 		var sameItem bool
 		newItems[i], sameItem = item.eval(valueMap)
 		same = same && sameItem
 	}
 	if same {
 		res = l
 	} else {
 		res = &listExpr{newItems}
 	}
 	return
 }

 func (l *listExpr) emit(gctx *generationContext) {
 	if !gctx.inAssignment || len(l.items) < 2 {
 		gctx.write("[")
 		sep := ""
 		for _, item := range l.items {
 			gctx.write(sep)
 			item.emit(gctx)
 			sep = ", "
 		}
 		gctx.write("]")
 		return
 	}

 	gctx.write("[")
 	gctx.indentLevel += 2

 	for _, item := range l.items {
 		gctx.newLine()
 		item.emit(gctx)
 		gctx.write(",")
 	}
 	gctx.indentLevel -= 2
 	gctx.newLine()
 	gctx.write("]")
 }

 func (_ *listExpr) typ() starlarkType {
 	return starlarkTypeList
 }

 func (l *listExpr) emitListVarCopy(gctx *generationContext) {
 	l.emit(gctx)
 }

 func newStringListExpr(items []string) *listExpr {
 	v := listExpr{}
 	for _, item := range items {
 		v.items = append(v.items, &stringLiteralExpr{item})
 	}
 	return &v
 }

 // concatExpr generates epxr1 + expr2 + ... + exprN in Starlark.
 type concatExpr struct {
 	items []starlarkExpr
 }

 func (c *concatExpr) emit(gctx *generationContext) {
 	if len(c.items) == 1 {
 		c.items[0].emit(gctx)
 		return
 	}

 	if !gctx.inAssignment {
 		c.items[0].emit(gctx)
 		for _, item := range c.items[1:] {
 			gctx.write(" + ")
 			item.emit(gctx)
 		}
 		return
 	}
 	gctx.write("(")
 	c.items[0].emit(gctx)
 	gctx.indentLevel += 2
 	for _, item := range c.items[1:] {
 		gctx.write(" +")
 		gctx.newLine()
 		item.emit(gctx)
 	}
 	gctx.write(")")
 	gctx.indentLevel -= 2
 }

 func (c *concatExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	same = true
 	xConcat := &concatExpr{items: make([]starlarkExpr, len(c.items))}
 	for i, item := range c.items {
 		var sameItem bool
 		xConcat.items[i], sameItem = item.eval(valueMap)
 		same = same && sameItem
 	}
 	if same {
 		res = c
 	} else {
 		res = xConcat
 	}
 	return
 }

 func (_ *concatExpr) typ() starlarkType {
 	return starlarkTypeList
 }

 func (c *concatExpr) emitListVarCopy(gctx *generationContext) {
 	c.emit(gctx)
 }

 // inExpr generates <expr> [not] in <list>
 type inExpr struct {
 	expr  starlarkExpr
 	list  starlarkExpr
 	isNot bool
 }

 func (i *inExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	x := &inExpr{isNot: i.isNot}
 	var sameExpr, sameList bool
 	x.expr, sameExpr = i.expr.eval(valueMap)
 	x.list, sameList = i.list.eval(valueMap)
 	if same = sameExpr && sameList; same {
 		res = i
 	} else {
 		res = x
 	}
 	return
 }

 func (i *inExpr) emit(gctx *generationContext) {
 	i.expr.emit(gctx)
 	if i.isNot {
 		gctx.write(" not in ")
 	} else {
 		gctx.write(" in ")
 	}
 	i.list.emit(gctx)
 }

 func (_ *inExpr) typ() starlarkType {
 	return starlarkTypeBool
 }

 func (i *inExpr) emitListVarCopy(gctx *generationContext) {
 	i.emit(gctx)
 }

 type indexExpr struct {
 	array starlarkExpr
 	index starlarkExpr
 }

 func (ix indexExpr) emit(gctx *generationContext) {
 	ix.array.emit(gctx)
 	gctx.write("[")
 	ix.index.emit(gctx)
 	gctx.write("]")
 }

 func (ix indexExpr) typ() starlarkType {
 	return starlarkTypeString
 }

 func (ix indexExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	newArray, isSameArray := ix.array.eval(valueMap)
 	newIndex, isSameIndex := ix.index.eval(valueMap)
 	if same = isSameArray && isSameIndex; same {
 		res = ix
 	} else {
 		res = &indexExpr{newArray, newIndex}
 	}
 	return
 }

 func (ix indexExpr) emitListVarCopy(gctx *generationContext) {
 	ix.emit(gctx)
 }

 type callExpr struct {
 	object     starlarkExpr // nil if static call
 	name       string
 	args       []starlarkExpr
 	returnType starlarkType
 }

 func (cx *callExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	newCallExpr := &callExpr{name: cx.name, args: make([]starlarkExpr, len(cx.args)),
 		returnType: cx.returnType}
 	if cx.object != nil {
 		newCallExpr.object, same = cx.object.eval(valueMap)
 	} else {
 		same = true
 	}
 	for i, args := range cx.args {
 		var s bool
 		newCallExpr.args[i], s = args.eval(valueMap)
 		same = same && s
 	}
 	if same {
 		res = cx
 	} else {
 		res = newCallExpr
 	}
 	return
 }

 func (cx *callExpr) emit(gctx *generationContext) {
 	sep := ""
 	if cx.object != nil {
 		gctx.write("(")
 		cx.object.emit(gctx)
 		gctx.write(")")
 		gctx.write(".", cx.name, "(")
 	} else {
 		kf, found := knownFunctions[cx.name]
 		if !found {
 			panic(fmt.Errorf("callExpr with unknown function %q", cx.name))
 		}
 		if kf.runtimeName[0] == '!' {
 			panic(fmt.Errorf("callExpr for %q should not be there", cx.name))
 		}
 		gctx.write(kf.runtimeName, "(")
 		if kf.hiddenArg == hiddenArgGlobal {
 			gctx.write("g")
 			sep = ", "
 		} else if kf.hiddenArg == hiddenArgConfig {
 			gctx.write("cfg")
 			sep = ", "
 		}
 	}
 	for _, arg := range cx.args {
 		gctx.write(sep)
 		arg.emit(gctx)
 		sep = ", "
 	}
 	gctx.write(")")
 }

 func (cx *callExpr) typ() starlarkType {
 	return cx.returnType
 }

 func (cx *callExpr) emitListVarCopy(gctx *generationContext) {
 	cx.emit(gctx)
 }

 type badExpr struct {
 	node    mkparser.Node
 	message string
 }

 func (b *badExpr) eval(_ map[string]starlarkExpr) (res starlarkExpr, same bool) {
 	res = b
 	same = true
 	return
 }

 func (b *badExpr) emit(_ *generationContext) {
 	panic("implement me")
 }

 func (_ *badExpr) typ() starlarkType {
 	return starlarkTypeUnknown
 }

 func (b *badExpr) emitListVarCopy(gctx *generationContext) {
 	panic("implement me")
 }

 func maybeConvertToStringList(expr starlarkExpr) starlarkExpr {
 	if xString, ok := expr.(*stringLiteralExpr); ok {
 		return newStringListExpr(strings.Fields(xString.literal))
 	}
 	return expr
 }

 func isEmptyString(expr starlarkExpr) bool {
 	x, ok := expr.(*stringLiteralExpr)
 	return ok && x.literal == ""
 }
	// Copyright 2021 Google LLC
	//
	// 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 mk2rbc

	import (
	"fmt"
	"strconv"
	"strings"

	mkparser "android/soong/androidmk/parser"
	)

	// Represents an expression in the Starlark code. An expression has
	// a type, and it can be evaluated.
	type starlarkExpr interface {
	starlarkNode
	typ() starlarkType
	// Try to substitute variable values. Return substitution result
	// and whether it is the same as the original expression.
	eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool)
	// Emit the code to copy the expression, otherwise we will end up
	// with source and target pointing to the same list.
	emitListVarCopy(gctx *generationContext)
	}

	func maybeString(expr starlarkExpr) (string, bool) {
	if x, ok := expr.(*stringLiteralExpr); ok {
	return x.literal, true
	}
	return "", false
	}

	type stringLiteralExpr struct {
	literal string
	}

	func (s *stringLiteralExpr) eval(_ map[string]starlarkExpr) (res starlarkExpr, same bool) {
	res = s
	same = true
	return
	}

	func (s stringLiteralExpr) emit(gctx generationContext) {
	gctx.writef("%q", s.literal)
	}

	func (_ *stringLiteralExpr) typ() starlarkType {
	return starlarkTypeString
	}

	func (s stringLiteralExpr) emitListVarCopy(gctx generationContext) {
	s.emit(gctx)
	}

	// Integer literal
	type intLiteralExpr struct {
	literal int
	}

	func (s *intLiteralExpr) eval(_ map[string]starlarkExpr) (res starlarkExpr, same bool) {
	res = s
	same = true
	return
	}

	func (s intLiteralExpr) emit(gctx generationContext) {
	gctx.writef("%d", s.literal)
	}

	func (_ *intLiteralExpr) typ() starlarkType {
	return starlarkTypeInt
	}

	func (s intLiteralExpr) emitListVarCopy(gctx generationContext) {
	s.emit(gctx)
	}

	// interpolateExpr represents Starlark's interpolation operator <string> % list
	// we break <string> into a list of chunks, i.e., "first%second%third" % (X, Y)
	// will have chunks = ["first", "second", "third"] and args = [X, Y]
	type interpolateExpr struct {
	chunks []string // string chunks, separated by '%'
	args []starlarkExpr
	}

	func (xi interpolateExpr) emit(gctx generationContext) {
	if len(xi.chunks) != len(xi.args)+1 {
	panic(fmt.Errorf("malformed interpolateExpr: #chunks(%d) != #args(%d)+1",
	len(xi.chunks), len(xi.args)))
	}
	// Generate format as join of chunks, but first escape '%' in them
	format := strings.ReplaceAll(xi.chunks[0], "%", "%%")
	for _, chunk := range xi.chunks[1:] {
	format += "%s" + strings.ReplaceAll(chunk, "%", "%%")
	}
	gctx.writef("%q %% ", format)
	emitarg := func(arg starlarkExpr) {
	if arg.typ() == starlarkTypeList {
	gctx.write(`" ".join(`)
	arg.emit(gctx)
	gctx.write(`)`)
	} else {
	arg.emit(gctx)
	}
	}
	if len(xi.args) == 1 {
	emitarg(xi.args[0])
	} else {
	sep := "("
	for _, arg := range xi.args {
	gctx.write(sep)
	emitarg(arg)
	sep = ", "
	}
	gctx.write(")")
	}
	}

	func (xi *interpolateExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
	same = true
	newChunks := []string{xi.chunks[0]}
	var newArgs []starlarkExpr
	for i, arg := range xi.args {
	newArg, sameArg := arg.eval(valueMap)
	same = same && sameArg
	switch x := newArg.(type) {
	case *stringLiteralExpr:
	newChunks[len(newChunks)-1] += x.literal + xi.chunks[i+1]
	same = false
	continue
	case *intLiteralExpr:
	newChunks[len(newChunks)-1] += strconv.Itoa(x.literal) + xi.chunks[i+1]
	same = false
	continue
	default:
	newChunks = append(newChunks, xi.chunks[i+1])
	newArgs = append(newArgs, newArg)
	}
	}
	if same {
	res = xi
	} else if len(newChunks) == 1 {
	res = &stringLiteralExpr{newChunks[0]}
	} else {
	res = &interpolateExpr{chunks: newChunks, args: newArgs}
	}
	return
	}

	func (_ *interpolateExpr) typ() starlarkType {
	return starlarkTypeString
	}

	func (xi interpolateExpr) emitListVarCopy(gctx generationContext) {
	xi.emit(gctx)
	}

	type variableRefExpr struct {
	ref variable
	isDefined bool
	}

	func (v *variableRefExpr) eval(map[string]starlarkExpr) (res starlarkExpr, same bool) {
	predefined, ok := v.ref.(*predefinedVariable)
	if same = !ok; same {
	res = v
	} else {
	res = predefined.value
	}
	return
	}

	func (v variableRefExpr) emit(gctx generationContext) {
	v.ref.emitGet(gctx, v.isDefined)
	}

	func (v *variableRefExpr) typ() starlarkType {
	return v.ref.valueType()
	}

	func (v variableRefExpr) emitListVarCopy(gctx generationContext) {
	v.emit(gctx)
	if v.typ() == starlarkTypeList {
	gctx.write("[:]") // this will copy the list
	}
	}

	type notExpr struct {
	expr starlarkExpr
	}

	func (n *notExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
	if x, same := n.expr.eval(valueMap); same {
	res = n
	} else {
	res = &notExpr{expr: x}
	}
	return
	}

	func (n notExpr) emit(ctx generationContext) {
	ctx.write("not ")
	n.expr.emit(ctx)
	}

	func (_ *notExpr) typ() starlarkType {
	return starlarkTypeBool
	}

	func (n notExpr) emitListVarCopy(gctx generationContext) {
	n.emit(gctx)
	}

	type eqExpr struct {
	left, right starlarkExpr
	isEq bool // if false, it's !=
	}

	func (eq *eqExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
	xLeft, sameLeft := eq.left.eval(valueMap)
	xRight, sameRight := eq.right.eval(valueMap)
	if same = sameLeft && sameRight; same {
	res = eq
	} else {
	res = &eqExpr{left: xLeft, right: xRight, isEq: eq.isEq}
	}
	return
	}

	func (eq eqExpr) emit(gctx generationContext) {
	emitSimple := func(expr starlarkExpr) {
	if eq.isEq {
	gctx.write("not ")
	}
	expr.emit(gctx)
	}
	// Are we checking that a variable is empty?
	if isEmptyString(eq.left) {
	emitSimple(eq.right)
	return
	} else if isEmptyString(eq.right) {
	emitSimple(eq.left)
	return

	}
	// General case
	eq.left.emit(gctx)
	if eq.isEq {
	gctx.write(" == ")
	} else {
	gctx.write(" != ")
	}
	eq.right.emit(gctx)
	}

	func (_ *eqExpr) typ() starlarkType {
	return starlarkTypeBool
	}

	func (eq eqExpr) emitListVarCopy(gctx generationContext) {
	eq.emit(gctx)
	}

	// variableDefinedExpr corresponds to Make's ifdef VAR
	type variableDefinedExpr struct {
	v variable
	}

	func (v *variableDefinedExpr) eval(_ map[string]starlarkExpr) (res starlarkExpr, same bool) {
	res = v
	same = true
	return

	}

	func (v variableDefinedExpr) emit(gctx generationContext) {
	if v.v != nil {
	v.v.emitDefined(gctx)
	return
	}
	gctx.writef("%s(%q)", cfnWarning, "TODO(VAR)")
	}

	func (_ *variableDefinedExpr) typ() starlarkType {
	return starlarkTypeBool
	}

	func (v variableDefinedExpr) emitListVarCopy(gctx generationContext) {
	v.emit(gctx)
	}

	type listExpr struct {
	items []starlarkExpr
	}

	func (l *listExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
	newItems := make([]starlarkExpr, len(l.items))
	same = true
	for i, item := range l.items {
	var sameItem bool
	newItems[i], sameItem = item.eval(valueMap)
	same = same && sameItem
	}
	if same {
	res = l
	} else {
	res = &listExpr{newItems}
	}
	return
	}

	func (l listExpr) emit(gctx generationContext) {
	if !gctx.inAssignment \|\| len(l.items) < 2 {
	gctx.write("[")
	sep := ""
	for _, item := range l.items {
	gctx.write(sep)
	item.emit(gctx)
	sep = ", "
	}
	gctx.write("]")
	return
	}

	gctx.write("[")
	gctx.indentLevel += 2

	for _, item := range l.items {
	gctx.newLine()
	item.emit(gctx)
	gctx.write(",")
	}
	gctx.indentLevel -= 2
	gctx.newLine()
	gctx.write("]")
	}

	func (_ *listExpr) typ() starlarkType {
	return starlarkTypeList
	}

	func (l listExpr) emitListVarCopy(gctx generationContext) {
	l.emit(gctx)
	}

	func newStringListExpr(items []string) *listExpr {
	v := listExpr{}
	for _, item := range items {
	v.items = append(v.items, &stringLiteralExpr{item})
	}
	return &v
	}

	// concatExpr generates epxr1 + expr2 + ... + exprN in Starlark.
	type concatExpr struct {
	items []starlarkExpr
	}

	func (c concatExpr) emit(gctx generationContext) {
	if len(c.items) == 1 {
	c.items[0].emit(gctx)
	return
	}

	if !gctx.inAssignment {
	c.items[0].emit(gctx)
	for _, item := range c.items[1:] {
	gctx.write(" + ")
	item.emit(gctx)
	}
	return
	}
	gctx.write("(")
	c.items[0].emit(gctx)
	gctx.indentLevel += 2
	for _, item := range c.items[1:] {
	gctx.write(" +")
	gctx.newLine()
	item.emit(gctx)
	}
	gctx.write(")")
	gctx.indentLevel -= 2
	}

	func (c *concatExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
	same = true
	xConcat := &concatExpr{items: make([]starlarkExpr, len(c.items))}
	for i, item := range c.items {
	var sameItem bool
	xConcat.items[i], sameItem = item.eval(valueMap)
	same = same && sameItem
	}
	if same {
	res = c
	} else {
	res = xConcat
	}
	return
	}

	func (_ *concatExpr) typ() starlarkType {
	return starlarkTypeList
	}

	func (c concatExpr) emitListVarCopy(gctx generationContext) {
	c.emit(gctx)
	}

	// inExpr generates <expr> [not] in <list>
	type inExpr struct {
	expr starlarkExpr
	list starlarkExpr
	isNot bool
	}

	func (i *inExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
	x := &inExpr{isNot: i.isNot}
	var sameExpr, sameList bool
	x.expr, sameExpr = i.expr.eval(valueMap)
	x.list, sameList = i.list.eval(valueMap)
	if same = sameExpr && sameList; same {
	res = i
	} else {
	res = x
	}
	return
	}

	func (i inExpr) emit(gctx generationContext) {
	i.expr.emit(gctx)
	if i.isNot {
	gctx.write(" not in ")
	} else {
	gctx.write(" in ")
	}
	i.list.emit(gctx)
	}

	func (_ *inExpr) typ() starlarkType {
	return starlarkTypeBool
	}

	func (i inExpr) emitListVarCopy(gctx generationContext) {
	i.emit(gctx)
	}

	type indexExpr struct {
	array starlarkExpr
	index starlarkExpr
	}

	func (ix indexExpr) emit(gctx *generationContext) {
	ix.array.emit(gctx)
	gctx.write("[")
	ix.index.emit(gctx)
	gctx.write("]")
	}

	func (ix indexExpr) typ() starlarkType {
	return starlarkTypeString
	}

	func (ix indexExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
	newArray, isSameArray := ix.array.eval(valueMap)
	newIndex, isSameIndex := ix.index.eval(valueMap)
	if same = isSameArray && isSameIndex; same {
	res = ix
	} else {
	res = &indexExpr{newArray, newIndex}
	}
	return
	}

	func (ix indexExpr) emitListVarCopy(gctx *generationContext) {
	ix.emit(gctx)
	}

	type callExpr struct {
	object starlarkExpr // nil if static call
	name string
	args []starlarkExpr
	returnType starlarkType
	}

	func (cx *callExpr) eval(valueMap map[string]starlarkExpr) (res starlarkExpr, same bool) {
	newCallExpr := &callExpr{name: cx.name, args: make([]starlarkExpr, len(cx.args)),
	returnType: cx.returnType}
	if cx.object != nil {
	newCallExpr.object, same = cx.object.eval(valueMap)
	} else {
	same = true
	}
	for i, args := range cx.args {
	var s bool
	newCallExpr.args[i], s = args.eval(valueMap)
	same = same && s
	}
	if same {
	res = cx
	} else {
	res = newCallExpr
	}
	return
	}

	func (cx callExpr) emit(gctx generationContext) {
	sep := ""
	if cx.object != nil {
	gctx.write("(")
	cx.object.emit(gctx)
	gctx.write(")")
	gctx.write(".", cx.name, "(")
	} else {
	kf, found := knownFunctions[cx.name]
	if !found {
	panic(fmt.Errorf("callExpr with unknown function %q", cx.name))
	}
	if kf.runtimeName[0] == '!' {
	panic(fmt.Errorf("callExpr for %q should not be there", cx.name))
	}
	gctx.write(kf.runtimeName, "(")
	if kf.hiddenArg == hiddenArgGlobal {
	gctx.write("g")
	sep = ", "
	} else if kf.hiddenArg == hiddenArgConfig {
	gctx.write("cfg")
	sep = ", "
	}
	}
	for _, arg := range cx.args {
	gctx.write(sep)
	arg.emit(gctx)
	sep = ", "
	}
	gctx.write(")")
	}

	func (cx *callExpr) typ() starlarkType {
	return cx.returnType
	}

	func (cx callExpr) emitListVarCopy(gctx generationContext) {
	cx.emit(gctx)
	}

	type badExpr struct {
	node mkparser.Node
	message string
	}

	func (b *badExpr) eval(_ map[string]starlarkExpr) (res starlarkExpr, same bool) {
	res = b
	same = true
	return
	}

	func (b badExpr) emit(_ generationContext) {
	panic("implement me")
	}

	func (_ *badExpr) typ() starlarkType {
	return starlarkTypeUnknown
	}

	func (b badExpr) emitListVarCopy(gctx generationContext) {
	panic("implement me")
	}

	func maybeConvertToStringList(expr starlarkExpr) starlarkExpr {
	if xString, ok := expr.(*stringLiteralExpr); ok {
	return newStringListExpr(strings.Fields(xString.literal))
	}
	return expr
	}

	func isEmptyString(expr starlarkExpr) bool {
	x, ok := expr.(*stringLiteralExpr)
	return ok && x.literal == ""
	}