private void visitObjectWithComputedProperty(Node obj, Node parent) {
Preconditions.checkArgument(obj.isObjectLit());
List<Node> props = new ArrayList<>();
Node currElement = obj.getFirstChild();
while (currElement != null) {
if (currElement.getBooleanProp(Node.COMPUTED_PROP_GETTER)
|| currElement.getBooleanProp(Node.COMPUTED_PROP_SETTER)) {
cannotConvertYet(currElement, "computed getter/setter");
return;
} else if (currElement.isGetterDef() || currElement.isSetterDef()) {
currElement = currElement.getNext();
} else {
Node nextNode = currElement.getNext();
obj.removeChild(currElement);
props.add(currElement);
currElement = nextNode;
}
}
String objName = FRESH_COMP_PROP_VAR + compiler.getUniqueNameIdSupplier().get();
props = Lists.reverse(props);
Node result = IR.name(objName);
for (Node propdef : props) {
if (propdef.isComputedProp()) {
Node propertyExpression = propdef.removeFirstChild();
Node value = propdef.removeFirstChild();
result =
IR.comma(IR.assign(IR.getelem(IR.name(objName), propertyExpression), value), result);
} else {
if (!propdef.hasChildren()) {
Node name = IR.name(propdef.getString()).useSourceInfoIfMissingFrom(propdef);
propdef.addChildToBack(name);
}
Node val = propdef.removeFirstChild();
propdef.setType(Token.STRING);
int type = propdef.isQuotedString() ? Token.GETELEM : Token.GETPROP;
Node access = new Node(type, IR.name(objName), propdef);
result = IR.comma(IR.assign(access, val), result);
}
}
Node statement = obj;
while (!NodeUtil.isStatement(statement)) {
statement = statement.getParent();
}
result.useSourceInfoIfMissingFromForTree(obj);
parent.replaceChild(obj, result);
Node var = IR.var(IR.name(objName), obj);
var.useSourceInfoIfMissingFromForTree(statement);
statement.getParent().addChildBefore(var, statement);
compiler.reportCodeChange();
}
@Override
public void visit(NodeTraversal t, Node n, Node parent) {
switch (n.getType()) {
case Token.OBJECTLIT:
for (Node child : n.children()) {
if (child.isComputedProp()) {
visitObjectWithComputedProperty(n, parent);
break;
}
}
break;
case Token.MEMBER_FUNCTION_DEF:
if (parent.isObjectLit()) {
visitMemberDefInObjectLit(n, parent);
}
break;
case Token.FOR_OF:
visitForOf(n, parent);
break;
case Token.STRING_KEY:
visitStringKey(n);
break;
case Token.CLASS:
for (Node member = n.getLastChild().getFirstChild();
member != null;
member = member.getNext()) {
if (member.getBooleanProp(Node.COMPUTED_PROP_GETTER)
|| member.getBooleanProp(Node.COMPUTED_PROP_SETTER)) {
cannotConvert(member, "computed getter or setter in class definition");
return;
}
}
visitClass(n, parent);
break;
case Token.ARRAYLIT:
case Token.NEW:
case Token.CALL:
for (Node child : n.children()) {
if (child.isSpread()) {
visitArrayLitOrCallWithSpread(n, parent);
break;
}
}
break;
case Token.TAGGED_TEMPLATELIT:
Es6TemplateLiterals.visitTaggedTemplateLiteral(t, n);
break;
case Token.TEMPLATELIT:
if (!parent.isTaggedTemplateLit()) {
Es6TemplateLiterals.visitTemplateLiteral(t, n);
}
break;
}
}
private void validateComputedPropClassMethod(Node n) {
validateNodeType(Token.COMPUTED_PROP, n);
validateExpression(n.getFirstChild());
if (n.getBooleanProp(Node.COMPUTED_PROP_VARIABLE)) {
validateChildCount(n, 1);
} else {
validateChildCount(n, 2);
validateFunctionExpression(n.getLastChild());
}
}
private void validateExport(Node n) {
validateNodeType(Token.EXPORT, n);
if (n.getBooleanProp(Node.EXPORT_ALL_FROM)) { // export * from "mod"
validateChildCount(n, 2);
validateNodeType(Token.EMPTY, n.getFirstChild());
validateString(n.getChildAtIndex(1));
} else if (n.getBooleanProp(Node.EXPORT_DEFAULT)) { // export default foo = 2
validateChildCount(n, 1);
validateExpression(n.getFirstChild());
} else {
validateChildCountIn(n, 1, 2);
if (n.getFirstChild().getType() == Token.EXPORT_SPECS) {
validateExportSpecifiers(n.getFirstChild());
} else {
validateStatement(n.getFirstChild());
}
if (n.getChildCount() == 2) {
validateString(n.getChildAtIndex(1));
}
}
}
/**
* Declares global variables to serve as aliases for the values in an object literal, optionally
* removing all of the object literal's keys and values.
*
* @param alias The object literal's flattened name (e.g. "a$b$c")
* @param objlit The OBJLIT node
* @param varNode The VAR node to which new global variables should be added as children
* @param nameToAddAfter The child of {@code varNode} after which new variables should be added
* (may be null)
* @param varParent {@code varNode}'s parent
* @return The number of variables added
*/
private int declareVarsForObjLitValues(
Name objlitName,
String alias,
Node objlit,
Node varNode,
Node nameToAddAfter,
Node varParent) {
int numVars = 0;
int arbitraryNameCounter = 0;
boolean discardKeys = !objlitName.shouldKeepKeys();
for (Node key = objlit.getFirstChild(), nextKey; key != null; key = nextKey) {
Node value = key.getFirstChild();
nextKey = key.getNext();
// A get or a set can not be rewritten as a VAR.
if (key.isGetterDef() || key.isSetterDef()) {
continue;
}
// We generate arbitrary names for keys that aren't valid JavaScript
// identifiers, since those keys are never referenced. (If they were,
// this object literal's child names wouldn't be collapsible.) The only
// reason that we don't eliminate them entirely is the off chance that
// their values are expressions that have side effects.
boolean isJsIdentifier = !key.isNumber() && TokenStream.isJSIdentifier(key.getString());
String propName = isJsIdentifier ? key.getString() : String.valueOf(++arbitraryNameCounter);
// If the name cannot be collapsed, skip it.
String qName = objlitName.getFullName() + '.' + propName;
Name p = nameMap.get(qName);
if (p != null && !p.canCollapse()) {
continue;
}
String propAlias = appendPropForAlias(alias, propName);
Node refNode = null;
if (discardKeys) {
objlit.removeChild(key);
value.detachFromParent();
} else {
// Substitute a reference for the value.
refNode = IR.name(propAlias);
if (key.getBooleanProp(Node.IS_CONSTANT_NAME)) {
refNode.putBooleanProp(Node.IS_CONSTANT_NAME, true);
}
key.replaceChild(value, refNode);
}
// Declare the collapsed name as a variable with the original value.
Node nameNode = IR.name(propAlias);
nameNode.addChildToFront(value);
if (key.getBooleanProp(Node.IS_CONSTANT_NAME)) {
nameNode.putBooleanProp(Node.IS_CONSTANT_NAME, true);
}
Node newVar = IR.var(nameNode).useSourceInfoIfMissingFromForTree(key);
if (nameToAddAfter != null) {
varParent.addChildAfter(newVar, nameToAddAfter);
} else {
varParent.addChildBefore(newVar, varNode);
}
compiler.reportCodeChange();
nameToAddAfter = newVar;
// Update the global name's node ancestry if it hasn't already been
// done. (Duplicate keys in an object literal can bring us here twice
// for the same global name.)
if (isJsIdentifier && p != null) {
if (!discardKeys) {
Ref newAlias = p.getDeclaration().cloneAndReclassify(Ref.Type.ALIASING_GET);
newAlias.node = refNode;
p.addRef(newAlias);
}
p.getDeclaration().node = nameNode;
if (value.isFunction()) {
checkForHosedThisReferences(value, key.getJSDocInfo(), p);
}
}
numVars++;
}
return numVars;
}
/**
* Classes are processed in 3 phases:
*
* <ol>
* <li>The class name is extracted.
* <li>Class members are processed and rewritten.
* <li>The constructor is built.
* </ol>
*/
private void visitClass(Node classNode, Node parent) {
checkClassReassignment(classNode);
// Collect Metadata
ClassDeclarationMetadata metadata = ClassDeclarationMetadata.create(classNode, parent);
if (metadata == null || metadata.fullClassName == null) {
cannotConvert(
parent,
"Can only convert classes that are declarations or the right hand"
+ " side of a simple assignment.");
return;
}
if (metadata.hasSuperClass() && !metadata.superClassNameNode.isQualifiedName()) {
compiler.report(JSError.make(metadata.superClassNameNode, DYNAMIC_EXTENDS_TYPE));
return;
}
boolean useUnique = NodeUtil.isStatement(classNode) && !NodeUtil.isInFunction(classNode);
String uniqueFullClassName =
useUnique ? getUniqueClassName(metadata.fullClassName) : metadata.fullClassName;
Node classNameAccess = NodeUtil.newQName(compiler, uniqueFullClassName);
Node prototypeAccess = NodeUtil.newPropertyAccess(compiler, classNameAccess, "prototype");
Preconditions.checkState(
NodeUtil.isStatement(metadata.insertionPoint),
"insertion point must be a statement: %s",
metadata.insertionPoint);
Node constructor = null;
JSDocInfo ctorJSDocInfo = null;
// Process all members of the class
Node classMembers = classNode.getLastChild();
Map<String, JSDocInfo> prototypeMembersToDeclare = new LinkedHashMap<>();
Map<String, JSDocInfo> classMembersToDeclare = new LinkedHashMap<>();
for (Node member : classMembers.children()) {
if (member.isEmpty()) {
continue;
}
Preconditions.checkState(
member.isMemberFunctionDef()
|| member.isGetterDef()
|| member.isSetterDef()
|| (member.isComputedProp() && !member.getBooleanProp(Node.COMPUTED_PROP_VARIABLE)),
"Member variables should have been transpiled earlier: ",
member);
if (member.isGetterDef() || member.isSetterDef()) {
JSTypeExpression typeExpr = getTypeFromGetterOrSetter(member).clone();
addToDefinePropertiesObject(metadata, member);
Map<String, JSDocInfo> membersToDeclare =
member.isStaticMember() ? classMembersToDeclare : prototypeMembersToDeclare;
JSDocInfo existingJSDoc = membersToDeclare.get(member.getString());
JSTypeExpression existingType = existingJSDoc == null ? null : existingJSDoc.getType();
if (existingType != null && !existingType.equals(typeExpr)) {
compiler.report(JSError.make(member, CONFLICTING_GETTER_SETTER_TYPE, member.getString()));
} else {
JSDocInfoBuilder jsDoc = new JSDocInfoBuilder(false);
jsDoc.recordType(typeExpr);
if (member.getJSDocInfo() != null && member.getJSDocInfo().isExport()) {
jsDoc.recordExport();
}
if (member.isStaticMember()) {
jsDoc.recordNoCollapse();
}
membersToDeclare.put(member.getString(), jsDoc.build());
}
} else if (member.isMemberFunctionDef() && member.getString().equals("constructor")) {
ctorJSDocInfo = member.getJSDocInfo();
constructor = member.getFirstChild().detachFromParent();
if (!metadata.anonymous) {
// Turns class Foo { constructor: function() {} } into function Foo() {},
// i.e. attaches the name the ctor function.
constructor.replaceChild(constructor.getFirstChild(), metadata.classNameNode.cloneNode());
}
} else {
Node qualifiedMemberAccess =
getQualifiedMemberAccess(compiler, member, classNameAccess, prototypeAccess);
Node method = member.getLastChild().detachFromParent();
Node assign = IR.assign(qualifiedMemberAccess, method);
assign.useSourceInfoIfMissingFromForTree(member);
JSDocInfo info = member.getJSDocInfo();
if (member.isStaticMember() && NodeUtil.referencesThis(assign.getLastChild())) {
JSDocInfoBuilder memberDoc = JSDocInfoBuilder.maybeCopyFrom(info);
memberDoc.recordThisType(
new JSTypeExpression(
new Node(Token.BANG, new Node(Token.QMARK)), member.getSourceFileName()));
info = memberDoc.build();
}
if (info != null) {
assign.setJSDocInfo(info);
}
Node newNode = NodeUtil.newExpr(assign);
metadata.insertNodeAndAdvance(newNode);
}
}
// Add declarations for properties that were defined with a getter and/or setter,
// so that the typechecker knows those properties exist on the class.
// This is a temporary solution. Eventually, the type checker should understand
// Object.defineProperties calls directly.
for (Map.Entry<String, JSDocInfo> entry : prototypeMembersToDeclare.entrySet()) {
String declaredMember = entry.getKey();
Node declaration = IR.getprop(prototypeAccess.cloneTree(), IR.string(declaredMember));
declaration.setJSDocInfo(entry.getValue());
metadata.insertNodeAndAdvance(
IR.exprResult(declaration).useSourceInfoIfMissingFromForTree(classNode));
}
for (Map.Entry<String, JSDocInfo> entry : classMembersToDeclare.entrySet()) {
String declaredMember = entry.getKey();
Node declaration = IR.getprop(classNameAccess.cloneTree(), IR.string(declaredMember));
declaration.setJSDocInfo(entry.getValue());
metadata.insertNodeAndAdvance(
IR.exprResult(declaration).useSourceInfoIfMissingFromForTree(classNode));
}
if (metadata.definePropertiesObjForPrototype.hasChildren()) {
Node definePropsCall =
IR.exprResult(
IR.call(
NodeUtil.newQName(compiler, "Object.defineProperties"),
prototypeAccess.cloneTree(),
metadata.definePropertiesObjForPrototype));
definePropsCall.useSourceInfoIfMissingFromForTree(classNode);
metadata.insertNodeAndAdvance(definePropsCall);
}
if (metadata.definePropertiesObjForClass.hasChildren()) {
Node definePropsCall =
IR.exprResult(
IR.call(
NodeUtil.newQName(compiler, "Object.defineProperties"),
classNameAccess.cloneTree(),
metadata.definePropertiesObjForClass));
definePropsCall.useSourceInfoIfMissingFromForTree(classNode);
metadata.insertNodeAndAdvance(definePropsCall);
}
Preconditions.checkNotNull(constructor);
JSDocInfo classJSDoc = NodeUtil.getBestJSDocInfo(classNode);
JSDocInfoBuilder newInfo = JSDocInfoBuilder.maybeCopyFrom(classJSDoc);
newInfo.recordConstructor();
if (metadata.hasSuperClass()) {
String superClassString = metadata.superClassNameNode.getQualifiedName();
if (newInfo.isInterfaceRecorded()) {
newInfo.recordExtendedInterface(
new JSTypeExpression(
new Node(Token.BANG, IR.string(superClassString)),
metadata.superClassNameNode.getSourceFileName()));
} else {
Node inherits =
IR.call(
NodeUtil.newQName(compiler, INHERITS),
NodeUtil.newQName(compiler, metadata.fullClassName),
NodeUtil.newQName(compiler, superClassString));
Node inheritsCall = IR.exprResult(inherits);
compiler.needsEs6Runtime = true;
inheritsCall.useSourceInfoIfMissingFromForTree(classNode);
Node enclosingStatement = NodeUtil.getEnclosingStatement(classNode);
enclosingStatement.getParent().addChildAfter(inheritsCall, enclosingStatement);
newInfo.recordBaseType(
new JSTypeExpression(
new Node(Token.BANG, IR.string(superClassString)),
metadata.superClassNameNode.getSourceFileName()));
}
}
// Classes are @struct by default.
if (!newInfo.isUnrestrictedRecorded()
&& !newInfo.isDictRecorded()
&& !newInfo.isStructRecorded()) {
newInfo.recordStruct();
}
if (ctorJSDocInfo != null) {
newInfo.recordSuppressions(ctorJSDocInfo.getSuppressions());
for (String param : ctorJSDocInfo.getParameterNames()) {
newInfo.recordParameter(param, ctorJSDocInfo.getParameterType(param));
}
newInfo.mergePropertyBitfieldFrom(ctorJSDocInfo);
}
if (NodeUtil.isStatement(classNode)) {
constructor.getFirstChild().setString("");
Node ctorVar = IR.let(metadata.classNameNode.cloneNode(), constructor);
ctorVar.useSourceInfoIfMissingFromForTree(classNode);
parent.replaceChild(classNode, ctorVar);
} else {
parent.replaceChild(classNode, constructor);
}
if (NodeUtil.isStatement(constructor)) {
constructor.setJSDocInfo(newInfo.build());
} else if (parent.isName()) {
// The constructor function is the RHS of a var statement.
// Add the JSDoc to the VAR node.
Node var = parent.getParent();
var.setJSDocInfo(newInfo.build());
} else if (constructor.getParent().isName()) {
// Is a newly created VAR node.
Node var = constructor.getParent().getParent();
var.setJSDocInfo(newInfo.build());
} else if (parent.isAssign()) {
// The constructor function is the RHS of an assignment.
// Add the JSDoc to the ASSIGN node.
parent.setJSDocInfo(newInfo.build());
} else {
throw new IllegalStateException("Unexpected parent node " + parent);
}
compiler.reportCodeChange();
}
private void validateIsSynthetic(Node n) {
if (!n.getBooleanProp(Node.SYNTHETIC_BLOCK_PROP)) {
violation("Missing 'synthetic block' annotation.", n);
}
}
/** @param fnNode A node for a function for which to generate a type annotation */
private String getFunctionAnnotation(Node fnNode) {
Preconditions.checkState(fnNode.isFunction());
StringBuilder sb = new StringBuilder("/**\n");
JSType type = fnNode.getJSType();
if (type == null || type.isUnknownType()) {
return "";
}
FunctionType funType = type.toMaybeFunctionType();
// We need to use the child nodes of the function as the nodes for the
// parameters of the function type do not have the real parameter names.
// FUNCTION
// NAME
// LP
// NAME param1
// NAME param2
if (fnNode != null) {
Node paramNode = NodeUtil.getFunctionParameters(fnNode).getFirstChild();
// Param types
for (Node n : funType.getParameters()) {
// Bail out if the paramNode is not there.
if (paramNode == null) {
break;
}
sb.append(" * ");
appendAnnotation(sb, "param", getParameterNodeJSDocType(n));
sb.append(" ").append(paramNode.getString()).append("\n");
paramNode = paramNode.getNext();
}
}
// Return type
JSType retType = funType.getReturnType();
if (retType != null && !retType.isUnknownType() && !retType.isEmptyType()) {
sb.append(" * ");
appendAnnotation(sb, "return", retType.toAnnotationString());
sb.append("\n");
}
// Constructor/interface
if (funType.isConstructor() || funType.isInterface()) {
FunctionType superConstructor = funType.getSuperClassConstructor();
if (superConstructor != null) {
ObjectType superInstance = funType.getSuperClassConstructor().getInstanceType();
if (!superInstance.toString().equals("Object")) {
sb.append(" * ");
appendAnnotation(sb, "extends", superInstance.toAnnotationString());
sb.append("\n");
}
}
if (funType.isInterface()) {
for (ObjectType interfaceType : funType.getExtendedInterfaces()) {
sb.append(" * ");
appendAnnotation(sb, "extends", interfaceType.toAnnotationString());
sb.append("\n");
}
}
// Avoid duplicates, add implemented type to a set first
Set<String> interfaces = Sets.newTreeSet();
for (ObjectType interfaze : funType.getImplementedInterfaces()) {
interfaces.add(interfaze.toAnnotationString());
}
for (String interfaze : interfaces) {
sb.append(" * ");
appendAnnotation(sb, "implements", interfaze);
sb.append("\n");
}
if (funType.isConstructor()) {
sb.append(" * @constructor\n");
} else if (funType.isInterface()) {
sb.append(" * @interface\n");
}
}
if (fnNode != null && fnNode.getBooleanProp(Node.IS_DISPATCHER)) {
sb.append(" * @javadispatch\n");
}
sb.append(" */\n");
return sb.toString();
}
