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gwt / gwt / 93508c6ff69814c8db3281de3912608961c73435 / . / dev / core / src / com / google / gwt / dev / jjs / impl / GenerateJavaScriptAST.java
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/*
* Copyright 2008 Google Inc.
*
* 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 com.google.gwt.dev.jjs.impl;
import static com.google.gwt.dev.js.JsUtils.createAssignment;
import static com.google.gwt.dev.js.JsUtils.createInvocationOrPropertyAccess;
import static com.google.gwt.dev.js.JsUtils.createQualifiedNameRef;
import com.google.gwt.core.ext.TreeLogger;
import com.google.gwt.core.ext.linker.impl.StandardSymbolData;
import com.google.gwt.dev.CompilerContext;
import com.google.gwt.dev.MinimalRebuildCache;
import com.google.gwt.dev.PrecompileTaskOptions;
import com.google.gwt.dev.cfg.PermutationProperties;
import com.google.gwt.dev.common.InliningMode;
import com.google.gwt.dev.javac.JsInteropUtil;
import com.google.gwt.dev.jjs.HasSourceInfo;
import com.google.gwt.dev.jjs.InternalCompilerException;
import com.google.gwt.dev.jjs.SourceInfo;
import com.google.gwt.dev.jjs.SourceOrigin;
import com.google.gwt.dev.jjs.ast.Context;
import com.google.gwt.dev.jjs.ast.HasEnclosingType;
import com.google.gwt.dev.jjs.ast.HasJsInfo.JsMemberType;
import com.google.gwt.dev.jjs.ast.HasName;
import com.google.gwt.dev.jjs.ast.JAbstractMethodBody;
import com.google.gwt.dev.jjs.ast.JArrayLength;
import com.google.gwt.dev.jjs.ast.JArrayRef;
import com.google.gwt.dev.jjs.ast.JArrayType;
import com.google.gwt.dev.jjs.ast.JBinaryOperation;
import com.google.gwt.dev.jjs.ast.JBinaryOperator;
import com.google.gwt.dev.jjs.ast.JBlock;
import com.google.gwt.dev.jjs.ast.JBreakStatement;
import com.google.gwt.dev.jjs.ast.JCaseStatement;
import com.google.gwt.dev.jjs.ast.JCastMap;
import com.google.gwt.dev.jjs.ast.JCastOperation;
import com.google.gwt.dev.jjs.ast.JClassLiteral;
import com.google.gwt.dev.jjs.ast.JClassType;
import com.google.gwt.dev.jjs.ast.JConditional;
import com.google.gwt.dev.jjs.ast.JConstructor;
import com.google.gwt.dev.jjs.ast.JContinueStatement;
import com.google.gwt.dev.jjs.ast.JDeclarationStatement;
import com.google.gwt.dev.jjs.ast.JDeclaredType;
import com.google.gwt.dev.jjs.ast.JDoStatement;
import com.google.gwt.dev.jjs.ast.JExpression;
import com.google.gwt.dev.jjs.ast.JExpressionStatement;
import com.google.gwt.dev.jjs.ast.JField;
import com.google.gwt.dev.jjs.ast.JFieldRef;
import com.google.gwt.dev.jjs.ast.JForStatement;
import com.google.gwt.dev.jjs.ast.JIfStatement;
import com.google.gwt.dev.jjs.ast.JInterfaceType;
import com.google.gwt.dev.jjs.ast.JLabel;
import com.google.gwt.dev.jjs.ast.JLabeledStatement;
import com.google.gwt.dev.jjs.ast.JLiteral;
import com.google.gwt.dev.jjs.ast.JLocal;
import com.google.gwt.dev.jjs.ast.JLocalRef;
import com.google.gwt.dev.jjs.ast.JMember;
import com.google.gwt.dev.jjs.ast.JMethod;
import com.google.gwt.dev.jjs.ast.JMethodBody;
import com.google.gwt.dev.jjs.ast.JMethodCall;
import com.google.gwt.dev.jjs.ast.JNameOf;
import com.google.gwt.dev.jjs.ast.JNewInstance;
import com.google.gwt.dev.jjs.ast.JNode;
import com.google.gwt.dev.jjs.ast.JNullLiteral;
import com.google.gwt.dev.jjs.ast.JNumericEntry;
import com.google.gwt.dev.jjs.ast.JParameter;
import com.google.gwt.dev.jjs.ast.JParameterRef;
import com.google.gwt.dev.jjs.ast.JPermutationDependentValue;
import com.google.gwt.dev.jjs.ast.JPostfixOperation;
import com.google.gwt.dev.jjs.ast.JPrefixOperation;
import com.google.gwt.dev.jjs.ast.JPrimitiveType;
import com.google.gwt.dev.jjs.ast.JProgram;
import com.google.gwt.dev.jjs.ast.JReferenceType;
import com.google.gwt.dev.jjs.ast.JReturnStatement;
import com.google.gwt.dev.jjs.ast.JRunAsync;
import com.google.gwt.dev.jjs.ast.JStatement;
import com.google.gwt.dev.jjs.ast.JSwitchStatement;
import com.google.gwt.dev.jjs.ast.JThisRef;
import com.google.gwt.dev.jjs.ast.JThrowStatement;
import com.google.gwt.dev.jjs.ast.JTransformer;
import com.google.gwt.dev.jjs.ast.JTryStatement;
import com.google.gwt.dev.jjs.ast.JType;
import com.google.gwt.dev.jjs.ast.JUnaryOperator;
import com.google.gwt.dev.jjs.ast.JUnsafeTypeCoercion;
import com.google.gwt.dev.jjs.ast.JVariable;
import com.google.gwt.dev.jjs.ast.JVisitor;
import com.google.gwt.dev.jjs.ast.JWhileStatement;
import com.google.gwt.dev.jjs.ast.RuntimeConstants;
import com.google.gwt.dev.jjs.ast.js.JDebuggerStatement;
import com.google.gwt.dev.jjs.ast.js.JMultiExpression;
import com.google.gwt.dev.jjs.ast.js.JsniClassLiteral;
import com.google.gwt.dev.jjs.ast.js.JsniFieldRef;
import com.google.gwt.dev.jjs.ast.js.JsniMethodBody;
import com.google.gwt.dev.jjs.ast.js.JsniMethodRef;
import com.google.gwt.dev.jjs.ast.js.JsonArray;
import com.google.gwt.dev.jjs.impl.ResolveRuntimeTypeReferences.TypeMapper;
import com.google.gwt.dev.js.JsStackEmulator;
import com.google.gwt.dev.js.JsUtils;
import com.google.gwt.dev.js.JsUtils.InvocationStyle;
import com.google.gwt.dev.js.ast.JsArrayAccess;
import com.google.gwt.dev.js.ast.JsArrayLiteral;
import com.google.gwt.dev.js.ast.JsBinaryOperation;
import com.google.gwt.dev.js.ast.JsBinaryOperator;
import com.google.gwt.dev.js.ast.JsBlock;
import com.google.gwt.dev.js.ast.JsBreak;
import com.google.gwt.dev.js.ast.JsCase;
import com.google.gwt.dev.js.ast.JsCatch;
import com.google.gwt.dev.js.ast.JsConditional;
import com.google.gwt.dev.js.ast.JsContext;
import com.google.gwt.dev.js.ast.JsContinue;
import com.google.gwt.dev.js.ast.JsDebugger;
import com.google.gwt.dev.js.ast.JsDefault;
import com.google.gwt.dev.js.ast.JsDoWhile;
import com.google.gwt.dev.js.ast.JsEmpty;
import com.google.gwt.dev.js.ast.JsExprStmt;
import com.google.gwt.dev.js.ast.JsExpression;
import com.google.gwt.dev.js.ast.JsFor;
import com.google.gwt.dev.js.ast.JsFunction;
import com.google.gwt.dev.js.ast.JsIf;
import com.google.gwt.dev.js.ast.JsInvocation;
import com.google.gwt.dev.js.ast.JsLabel;
import com.google.gwt.dev.js.ast.JsLiteral;
import com.google.gwt.dev.js.ast.JsModVisitor;
import com.google.gwt.dev.js.ast.JsName;
import com.google.gwt.dev.js.ast.JsNameOf;
import com.google.gwt.dev.js.ast.JsNameRef;
import com.google.gwt.dev.js.ast.JsNew;
import com.google.gwt.dev.js.ast.JsNode;
import com.google.gwt.dev.js.ast.JsNormalScope;
import com.google.gwt.dev.js.ast.JsNullLiteral;
import com.google.gwt.dev.js.ast.JsNumberLiteral;
import com.google.gwt.dev.js.ast.JsNumericEntry;
import com.google.gwt.dev.js.ast.JsObjectLiteral;
import com.google.gwt.dev.js.ast.JsParameter;
import com.google.gwt.dev.js.ast.JsPositionMarker;
import com.google.gwt.dev.js.ast.JsPositionMarker.Type;
import com.google.gwt.dev.js.ast.JsPostfixOperation;
import com.google.gwt.dev.js.ast.JsPrefixOperation;
import com.google.gwt.dev.js.ast.JsProgram;
import com.google.gwt.dev.js.ast.JsReturn;
import com.google.gwt.dev.js.ast.JsRootScope;
import com.google.gwt.dev.js.ast.JsScope;
import com.google.gwt.dev.js.ast.JsStatement;
import com.google.gwt.dev.js.ast.JsStringLiteral;
import com.google.gwt.dev.js.ast.JsSwitch;
import com.google.gwt.dev.js.ast.JsSwitchMember;
import com.google.gwt.dev.js.ast.JsThisRef;
import com.google.gwt.dev.js.ast.JsThrow;
import com.google.gwt.dev.js.ast.JsTry;
import com.google.gwt.dev.js.ast.JsUnaryOperator;
import com.google.gwt.dev.js.ast.JsVars;
import com.google.gwt.dev.js.ast.JsVars.JsVar;
import com.google.gwt.dev.js.ast.JsWhile;
import com.google.gwt.dev.util.Pair;
import com.google.gwt.dev.util.StringInterner;
import com.google.gwt.dev.util.arg.OptionMethodNameDisplayMode;
import com.google.gwt.dev.util.arg.OptionOptimize;
import com.google.gwt.dev.util.collect.Stack;
import com.google.gwt.dev.util.log.speedtracer.CompilerEventType;
import com.google.gwt.dev.util.log.speedtracer.SpeedTracerLogger;
import com.google.gwt.dev.util.log.speedtracer.SpeedTracerLogger.Event;
import com.google.gwt.thirdparty.guava.common.base.Function;
import com.google.gwt.thirdparty.guava.common.base.Joiner;
import com.google.gwt.thirdparty.guava.common.base.Predicate;
import com.google.gwt.thirdparty.guava.common.base.Predicates;
import com.google.gwt.thirdparty.guava.common.collect.FluentIterable;
import com.google.gwt.thirdparty.guava.common.collect.ImmutableList;
import com.google.gwt.thirdparty.guava.common.collect.ImmutableSet;
import com.google.gwt.thirdparty.guava.common.collect.ImmutableSortedSet;
import com.google.gwt.thirdparty.guava.common.collect.Iterables;
import com.google.gwt.thirdparty.guava.common.collect.Lists;
import com.google.gwt.thirdparty.guava.common.collect.Maps;
import com.google.gwt.thirdparty.guava.common.collect.Sets;
import java.util.Arrays;
import java.util.Collections;
import java.util.List;
import java.util.Map;
import java.util.Map.Entry;
import java.util.Set;
import java.util.SortedSet;
import java.util.TreeMap;
/**
* Creates a JavaScript AST from a <code>JProgram</code> node.
*/
public class GenerateJavaScriptAST {
/**
* Finds the nodes that are targets of JNameOf so that a name is assigned to them.
*/
private class FindNameOfTargets extends JVisitor {
@Override
public void endVisit(JNameOf x, Context ctx) {
nameOfTargets.add(x.getNode());
}
}
private class CreateNamesAndScopesVisitor extends JVisitor {
/**
* Cache of computed Java source file names to URI strings for symbol
* export. By using a cache we also ensure the miminum number of String
* instances are serialized.
*/
private final Map<String, String> fileNameToUriString = Maps.newHashMap();
private final Stack<JsScope> scopeStack = new Stack<JsScope>();
private JMethod currentMethod;
@Override
public boolean visit(JProgram x, Context ctx) {
// Scopes and name objects need to be calculated within all types, even reference-only ones.
// This information is used to be able to detect and avoid name collisions during pretty or
// obfuscated JS variable name generation.
x.visitAllTypes(this);
return false;
}
@Override
public void endVisit(JArrayType x, Context ctx) {
JsName name = topScope.declareName(x.getName());
names.put(x, name);
recordSymbol(x, name);
}
@Override
public void endVisit(JClassType x, Context ctx) {
scopeStack.pop();
}
@Override
public void endVisit(JField x, Context ctx) {
JsName jsName;
if (x.isStatic()) {
jsName = topScope.declareName(mangleName(x), x.getName());
} else {
jsName = JjsUtils.requiresJsName(x)
? scopeStack.peek().declareUnobfuscatableName(x.getJsName())
: scopeStack.peek().declareName(mangleName(x), x.getName());
}
names.put(x, jsName);
recordSymbol(x, jsName);
}
@Override
public void endVisit(JInterfaceType x, Context ctx) {
scopeStack.pop();
}
@Override
public void endVisit(JLabel x, Context ctx) {
if (names.get(x) != null) {
return;
}
names.put(x, scopeStack.peek().declareName(x.getName()));
}
@Override
public void endVisit(JLocal x, Context ctx) {
// locals can conflict, that's okay just reuse the same variable
JsScope scope = scopeStack.peek();
JsName jsName = scope.declareName(x.getName());
names.put(x, jsName);
}
@Override
public void endVisit(JMethod x, Context ctx) {
if (doesNotHaveConcreteImplementation(x)) {
return;
}
scopeStack.pop();
}
@Override
public void endVisit(JParameter x, Context ctx) {
if (x.isVarargs() && currentMethod.isJsMethodVarargs()) {
names.put(x, scopeStack.peek().declareUnobfuscatableName("arguments"));
return;
}
names.put(x, scopeStack.peek().declareName(x.getName()));
}
@Override
public void endVisit(JProgram x, Context ctx) {
/*
* put the null method and field into objectScope since they can be
* referenced as instance on null-types (as determined by type flow)
*/
JMethod nullMethod = x.getNullMethod();
polymorphicNames.put(nullMethod, objectScope.declareName("$_nullMethod"));
JField nullField = x.getNullField();
JsName nullFieldName = objectScope.declareName("$_nullField");
names.put(nullField, nullFieldName);
/*
* Create names for instantiable array types since JProgram.traverse()
* doesn't iterate over them.
*/
for (JArrayType arrayType : program.getAllArrayTypes()) {
if (program.typeOracle.isInstantiatedType(arrayType)) {
accept(arrayType);
}
}
}
@Override
public boolean visit(JClassType x, Context ctx) {
// have I already been visited as a super type?
JsScope myScope = classScopes.get(x);
if (myScope != null) {
scopeStack.push(myScope);
return false;
}
// My seed function name
JsName jsName = topScope.declareName(JjsUtils.mangledNameString(x), x.getShortName());
names.put(x, jsName);
recordSymbol(x, jsName);
// My class scope
if (x.getSuperClass() == null) {
myScope = objectScope;
} else {
JsScope parentScope = classScopes.get(x.getSuperClass());
// Run my superclass first!
if (parentScope == null) {
accept(x.getSuperClass());
}
parentScope = classScopes.get(x.getSuperClass());
assert (parentScope != null);
/*
* WEIRD: we wedge the global interface scope in between object and all
* of its subclasses; this ensures that interface method names trump all
* (except Object method names)
*/
if (parentScope == objectScope) {
parentScope = interfaceScope;
}
myScope = new JsNormalScope(parentScope, "class " + x.getShortName());
}
classScopes.put(x, myScope);
scopeStack.push(myScope);
return true;
}
@Override
public boolean visit(JInterfaceType x, Context ctx) {
// interfaces have no name at run time
scopeStack.push(interfaceScope);
return true;
}
@Override
public boolean visit(JMethod x, Context ctx) {
currentMethod = x;
// my polymorphic name
String name = x.getName();
if (x.needsDynamicDispatch()) {
if (polymorphicNames.get(x) == null) {
JsName polyName = JjsUtils.requiresJsName(x)
? interfaceScope.declareUnobfuscatableName(x.getJsName())
: interfaceScope.declareName(mangleNameForPoly(x), name);
polymorphicNames.put(x, polyName);
}
}
if (doesNotHaveConcreteImplementation(x)) {
return false;
}
// my global name
JsName globalName = null;
assert x.getEnclosingType() != null;
String mangleName = mangleNameForGlobal(x);
if (JProgram.isClinit(x)) {
name = name + "_" + x.getEnclosingType().getShortName();
}
/*
* Only allocate a name for a function if it is native, not polymorphic,
* is a JNameOf target or stack-stripping is disabled.
*/
if (!stripStack || !polymorphicNames.containsKey(x) || x.isJsniMethod()
|| nameOfTargets.contains(x)) {
globalName = topScope.declareName(mangleName, name);
names.put(x, globalName);
recordSymbol(x, globalName);
}
JsFunction function;
if (x.isJsniMethod()) {
// set the global name of the JSNI peer
JsniMethodBody body = (JsniMethodBody) x.getBody();
function = body.getFunc();
function.setName(globalName);
} else {
/*
* It would be more correct here to check for an inline assignment, such
* as var foo = function blah() {} and introduce a separate scope for
* the function's name according to EcmaScript-262, but this would mess
* up stack traces by allowing two inner scope function names to
* obfuscate to the same identifier, making function names no longer a
* 1:1 mapping to obfuscated symbols. Leaving them in global scope
* causes no harm.
*/
function = new JsFunction(x.getSourceInfo(), topScope, globalName, !x.isJsNative());
}
jsFunctionsByJavaMethodBody.put(x.getBody(), function);
scopeStack.push(function.getScope());
// Don't traverse the method body of methods in referenceOnly types since those method bodies
// only exist in JS output of other modules it is their responsibility to handle their naming.
return !program.isReferenceOnly(x.getEnclosingType());
}
@Override
public boolean visit(JTryStatement x, Context ctx) {
accept(x.getTryBlock());
for (JTryStatement.CatchClause clause : x.getCatchClauses()) {
JLocalRef arg = clause.getArg();
JBlock catchBlock = clause.getBlock();
JsCatch jsCatch =
new JsCatch(x.getSourceInfo(), scopeStack.peek(), arg.getTarget().getName());
JsParameter jsParam = jsCatch.getParameter();
names.put(arg.getTarget(), jsParam.getName());
catchMap.put(catchBlock, jsCatch);
catchParamIdentifiers.add(jsParam.getName());
scopeStack.push(jsCatch.getScope());
accept(catchBlock);
scopeStack.pop();
}
// TODO: normalize this so it's never null?
if (x.getFinallyBlock() != null) {
accept(x.getFinallyBlock());
}
return false;
}
/**
* Generate a file name URI string for a source info, for symbol data
* export.
*/
private String makeUriString(HasSourceInfo x) {
String fileName = x.getSourceInfo().getFileName();
if (fileName == null) {
return null;
}
String uriString = fileNameToUriString.get(fileName);
if (uriString == null) {
uriString = StandardSymbolData.toUriString(fileName);
fileNameToUriString.put(fileName, uriString);
}
return uriString;
}
private void recordSymbol(JReferenceType type, JsName jsName) {
if (getRuntimeTypeReference(type) == null || !program.typeOracle.isInstantiatedType(type)) {
return;
}
String typeId = getRuntimeTypeReference(type).toSource();
StandardSymbolData symbolData =
StandardSymbolData.forClass(type.getName(), type.getSourceInfo().getFileName(),
type.getSourceInfo().getStartLine(), typeId);
assert !symbolTable.containsKey(symbolData);
symbolTable.put(symbolData, jsName);
}
private <T extends HasEnclosingType & HasName & HasSourceInfo> void recordSymbol(T member,
JsName jsName) {
/*
* NB: The use of member.getName() can produce confusion in cases where a type
* has both polymorphic and static dispatch for a method, because you
* might see HashSet::$add() and HashSet::add(). Logically, these methods
* should be treated equally, however they will be implemented with
* separate global functions and must be recorded independently.
*
* Automated systems that process the symbol information can easily map
* the statically-dispatched function by looking for method names that
* begin with a dollar-sign and whose first parameter is the enclosing
* type.
*/
String methodSignature = null;
if (member instanceof JMethod) {
JMethod method = ((JMethod) member);
methodSignature =
StringInterner.get().intern(method.getSignature().substring(method.getName().length()));
}
StandardSymbolData symbolData =
StandardSymbolData.forMember(member.getEnclosingType().getName(), member.getName(),
methodSignature, makeUriString(member), member.getSourceInfo().getStartLine());
assert !symbolTable.containsKey(symbolData) : "Duplicate symbol recorded " + jsName.getIdent()
+ " for " + member.getName() + " and key " + symbolData.getJsniIdent();
symbolTable.put(symbolData, jsName);
}
}
private class GenerateJavaScriptTransformer extends JTransformer<JsNode> {
public static final String GOOG_ABSTRACT_METHOD = "goog.abstractMethod";
public static final String GOOG_INHERITS = "goog.inherits";
public static final String GOOG_OBJECT_CREATE_SET = "goog.object.createSet";
private final Set<JDeclaredType> alreadyRan = Sets.newLinkedHashSet();
private final Map<JDeclaredType, JsFunction> clinitFunctionForType = Maps.newHashMap();
private JMethod currentMethod = null;
private final JsName arrayLength = objectScope.declareUnobfuscatableName("length");
private final JsName globalTemp = topScope.declareUnobfuscatableName("_");
private final JsName prototype = objectScope.declareUnobfuscatableName("prototype");
@Override
public JsExpression transformArrayLength(JArrayLength expression) {
assert expression.getInstance() != null : "Can't access the length of a null array";
return arrayLength.makeQualifiedRef(expression.getSourceInfo(),
transform(expression.getInstance()));
}
@Override
public JsExpression transformArrayRef(JArrayRef arrayRef) {
JsArrayAccess jsArrayAccess = new JsArrayAccess(arrayRef.getSourceInfo());
jsArrayAccess.setIndexExpr(transform(arrayRef.getIndexExpr()));
jsArrayAccess.setArrayExpr(transform(arrayRef.getInstance()));
return jsArrayAccess;
}
@Override
public JsExpression transformBinaryOperation(JBinaryOperation binaryOperation) {
JsExpression lhs = transform(binaryOperation.getLhs());
JsExpression rhs = transform(binaryOperation.getRhs());
JsBinaryOperator op = JavaToJsOperatorMap.get(binaryOperation.getOp());
/*
* Use === and !== on reference types, or else you can get wrong answers
* when Object.toString() == 'some string'.
*/
if (binaryOperation.getLhs().getType() instanceof JReferenceType
&& binaryOperation.getRhs().getType() instanceof JReferenceType) {
switch (op) {
case EQ:
op = JsBinaryOperator.REF_EQ;
break;
case NEQ:
op = JsBinaryOperator.REF_NEQ;
break;
}
}
return new JsBinaryOperation(binaryOperation.getSourceInfo(), op, lhs, rhs);
}
@Override
public JsStatement transformBlock(JBlock block) {
JsBlock jsBlock = new JsBlock(block.getSourceInfo());
List<JsStatement> stmts = jsBlock.getStatements();
transformIntoExcludingNulls(block.getStatements(), stmts);
Iterables.removeIf(stmts, Predicates.instanceOf(JsEmpty.class));
return jsBlock;
}
@Override
public JsNode transformBreakStatement(JBreakStatement breakStatement) {
SourceInfo info = breakStatement.getSourceInfo();
return new JsBreak(info, transformIntoLabelReference(info, breakStatement.getLabel()));
}
@Override
public JsNode transformCaseStatement(JCaseStatement caseStatement) {
if (caseStatement.getExpr() == null) {
return new JsDefault(caseStatement.getSourceInfo());
} else {
JsCase jsCase = new JsCase(caseStatement.getSourceInfo());
jsCase.setCaseExpr(transform(caseStatement.getExpr()));
return jsCase;
}
}
@Override
public JsNode transformCastOperation(JCastOperation castOperation) {
// These are left in when cast checking is disabled.
return transform(castOperation.getExpr());
}
@Override
public JsNode transformClassLiteral(JClassLiteral classLiteral) {
JsName classLit = names.get(classLiteral.getField());
return classLit.makeRef(classLiteral.getSourceInfo());
}
@Override
public JsNode transformDeclaredType(JDeclaredType type) {
// Don't generate JS for types not in current module if separate compilation is on.
if (program.isReferenceOnly(type)) {
return null;
}
if (alreadyRan.contains(type)) {
return null;
}
alreadyRan.add(type);
if (type.isJsNative()) {
// Emit JsOverlay static methods for native JsTypes.
emitStaticMethods(type);
// Emit JsOverlay (static) fields for native JsTypes.
emitFields(type);
return null;
}
checkForDuplicateMethods(type);
assert program.getTypeClassLiteralHolder() != type;
assert !program.immortalCodeGenTypes.contains(type);
// Super classes should be emitted before the actual class.
assert type.getSuperClass() == null || program.isReferenceOnly(type.getSuperClass()) ||
alreadyRan.contains(type.getSuperClass());
emitStaticMethods(type);
generateTypeSetup(type);
emitFields(type);
return null;
}
@Override
public JsNode transformConditional(JConditional conditional) {
JsExpression ifTest = transform(conditional.getIfTest());
JsExpression thenExpr = transform(conditional.getThenExpr());
JsExpression elseExpr = transform(conditional.getElseExpr());
return new JsConditional(conditional.getSourceInfo(), ifTest, thenExpr, elseExpr);
}
@Override
public JsNode transformContinueStatement(JContinueStatement continueStatement) {
SourceInfo info = continueStatement.getSourceInfo();
return new JsContinue(info, transformIntoLabelReference(info, continueStatement.getLabel()));
}
@Override
public JsNode transformDebuggerStatement(JDebuggerStatement debuggerStatement) {
return new JsDebugger(debuggerStatement.getSourceInfo());
}
@Override
public JsNode transformDeclarationStatement(JDeclarationStatement declarationStatement) {
if (declarationStatement.getInitializer() == null) {
return null;
}
JVariable target = declarationStatement.getVariableRef().getTarget();
if (target instanceof JField && initializeAtTopScope((JField) target)) {
// Will initialize at top scope; no need to double-initialize.
return null;
}
JsExpression initializer = transform(declarationStatement.getInitializer());
JsNameRef localRef = transform(declarationStatement.getVariableRef());
SourceInfo info = declarationStatement.getSourceInfo();
return JsUtils.createAssignment(info, localRef, initializer).makeStmt();
}
@Override
public JsNode transformDoStatement(JDoStatement doStatement) {
JsDoWhile stmt = new JsDoWhile(doStatement.getSourceInfo());
stmt.setCondition(transform(doStatement.getTestExpr()));
stmt.setBody(jsEmptyIfNull(doStatement.getSourceInfo(), transform(doStatement.getBody())));
return stmt;
}
@Override
public JsNode transformExpressionStatement(JExpressionStatement statement) {
return transform(statement.getExpr()).makeStmt();
}
@Override
public JsNode transformFieldRef(JFieldRef fieldRef) {
JsExpression qualifier = transform(fieldRef.getInstance());
boolean isStatic = fieldRef.getField().isStatic();
return isStatic ? dispatchToStaticField(fieldRef, qualifier)
: dispatchToInstanceField(fieldRef, qualifier);
}
private JsExpression dispatchToStaticField(
JFieldRef fieldRef, JsExpression unnecessaryQualifier) {
/*
* Note: the comma expressions here would cause an illegal tree state if
* the result expression ended up on the lhs of an assignment.
* {@link JsNormalizer} will fix this situation.
*/
JsExpression result = createStaticReference(fieldRef.getField(), fieldRef.getSourceInfo());
return JsUtils.createCommaExpression(
unnecessaryQualifier, maybeCreateClinitCall(fieldRef.getField()), result);
}
private JsExpression dispatchToInstanceField(JFieldRef x, JsExpression instance) {
return names.get(x.getField()).makeQualifiedRef(x.getSourceInfo(), instance);
}
@Override
public JsNode transformForStatement(JForStatement forStatement) {
JsFor result = new JsFor(forStatement.getSourceInfo());
JsExpression initExpr = null;
List<JsExprStmt> initStmts = transform(forStatement.getInitializers());
for (int i = 0; i < initStmts.size(); ++i) {
JsExprStmt initStmt = initStmts.get(i);
if (initStmt != null) {
initExpr = JsUtils.createCommaExpression(initExpr, initStmt.getExpression());
}
}
result.setInitExpr(initExpr);
result.setCondition(transform(forStatement.getCondition()));
result.setIncrExpr(transform(forStatement.getIncrements()));
result.setBody(jsEmptyIfNull(forStatement.getSourceInfo(), transform(forStatement.getBody())));
return result;
}
@Override
public JsNode transformIfStatement(JIfStatement ifStatement) {
JsIf result = new JsIf(ifStatement.getSourceInfo());
result.setIfExpr(transform(ifStatement.getIfExpr()));
result.setThenStmt(jsEmptyIfNull(ifStatement.getSourceInfo(),
transform(ifStatement.getThenStmt())));
result.setElseStmt(transform(ifStatement.getElseStmt()));
return result;
}
@Override
public JsLabel transformLabel(JLabel label) {
return new JsLabel(label.getSourceInfo(), names.get(label));
}
@Override
public JsStatement transformLabeledStatement(JLabeledStatement labeledStatement) {
JsLabel label = transform(labeledStatement.getLabel());
label.setStmt(transform(labeledStatement.getBody()));
return label;
}
@Override
public JsLiteral transformLiteral(JLiteral literal) {
return JjsUtils.translateLiteral(literal);
}
@Override
public JsNode transformLocalRef(JLocalRef localRef) {
return names.get(localRef.getTarget()).makeRef(localRef.getSourceInfo());
}
@Override
public JsNode transformMethod(JMethod method) {
if (method.isAbstract()) {
return generateAbstractMethodDefinition(method);
} else if (doesNotHaveConcreteImplementation(method)) {
return null;
}
currentMethod = method;
JsFunction function = transform(method.getBody());
function.setInliningMode(method.getInliningMode());
if (!method.isJsniMethod()) {
// Setup params on the generated function. A native method already got
// its jsParams set when parsed from JSNI.
List<JParameter> parameterList = method.getParams();
if (method.isJsMethodVarargs()) {
parameterList = parameterList.subList(0, parameterList.size() - 1);
}
transformInto(parameterList, function.getParameters());
}
JsInvocation jsInvocation = maybeCreateClinitCall(method);
if (jsInvocation != null) {
function.getBody().getStatements().add(0, jsInvocation.makeStmt());
}
if (JProgram.isClinit(method)) {
function.markAsClinit();
}
currentMethod = null;
return function;
}
@Override
public JsNode transformMethodBody(JMethodBody methodBody) {
JsBlock body = transform(methodBody.getBlock());
JsFunction function = jsFunctionsByJavaMethodBody.get(methodBody);
function.setBody(body);
/*
* Emit a statement to declare the method's complete set of local
* variables. JavaScript doesn't have the same concept of lexical scoping
* as Java, so it's okay to just predeclare all local vars at the top of
* the function, which saves us having to use the "var" keyword over and
* over.
*
* Note: it's fine to use the same JS ident to represent two different
* Java locals of the same name since they could never conflict with each
* other in Java. We use the alreadySeen set to make sure we don't declare
* the same-named local var twice.
*/
JsVars vars = new JsVars(methodBody.getSourceInfo());
Set<String> alreadySeen = Sets.newHashSet();
for (JLocal local : methodBody.getLocals()) {
JsName name = names.get(local);
String ident = name.getIdent();
if (!alreadySeen.contains(ident)
// Catch block params don't need var declarations
&& !catchParamIdentifiers.contains(name)) {
alreadySeen.add(ident);
vars.add(new JsVar(methodBody.getSourceInfo(), name));
}
}
if (!vars.isEmpty()) {
function.getBody().getStatements().add(0, vars);
}
return function;
}
@Override
public JsNode transformMethodCall(JMethodCall methodCall) {
JMethod method = methodCall.getTarget();
if (JProgram.isClinit(method)) {
/*
* It is possible for clinits to be referenced here that have actually
* been retargeted (see {@link
* JTypeOracle.recomputeAfterOptimizations}). Most of the time, these
* will get cleaned up by other optimization passes prior to this point,
* but it's not guaranteed. In this case we need to replace the method
* call with the replaced clinit, unless the replacement is null, in
* which case we generate a JsNullLiteral as a place-holder expression.
*/
JDeclaredType type = method.getEnclosingType();
JDeclaredType clinitTarget = type.getClinitTarget();
if (clinitTarget == null) {
// generate a null expression, which will get optimized out
return JsNullLiteral.INSTANCE;
}
method = clinitTarget.getClinitMethod();
}
JsExpression qualifier = transform(methodCall.getInstance());
List<JsExpression> args = transform(methodCall.getArgs());
SourceInfo sourceInfo = methodCall.getSourceInfo();
if (method.isStatic()) {
return dispatchToStatic(qualifier, method, args, sourceInfo);
} else if (methodCall.isStaticDispatchOnly()) {
return dispatchToSuper(qualifier, method, args, sourceInfo);
} else if (method.isOrOverridesJsFunctionMethod()) {
return dispatchToJsFunction(qualifier, method, args, sourceInfo);
} else {
return dispatchToInstanceMethod(qualifier, method, args, sourceInfo);
}
}
private JsExpression dispatchToStatic(JsExpression unnecessaryQualifier, JMethod method,
List<JsExpression> args, SourceInfo sourceInfo) {
JsNameRef methodName = createStaticReference(method, sourceInfo);
return JsUtils.createCommaExpression(
unnecessaryQualifier,
createInvocationOrPropertyAccess(
InvocationStyle.NORMAL, sourceInfo, method, null, methodName, args));
}
private JsExpression dispatchToSuper(
JsExpression instance, JMethod method, List<JsExpression> args, SourceInfo sourceInfo) {
JsNameRef methodNameRef;
if (method.isJsNative()) {
// Construct Constructor.prototype.jsname or Constructor.
methodNameRef = createGlobalQualifier(method.getQualifiedJsName(), sourceInfo);
} else if (method.isConstructor()) {
/*
* Constructor calls through {@code this} and {@code super} are always dispatched statically
* using the constructor function name (constructors are always defined as top level
* functions).
*
* Because constructors are modeled like instance methods they have an implicit {@code this}
* parameter, hence they are invoked like: "constructor.call(this, ...)".
*/
methodNameRef = names.get(method).makeRef(sourceInfo);
} else {
// These are regular super method call. These calls are always dispatched statically and
// optimizations will devirtualize them (except in a few cases, like being target of
// {@link Impl.getNameOf} or calls to the native classes.
JDeclaredType superClass = method.getEnclosingType();
JsExpression protoRef = getPrototypeQualifierViaLookup(superClass, sourceInfo);
methodNameRef = polymorphicNames.get(method).makeQualifiedRef(sourceInfo, protoRef);
}
return JsUtils.createInvocationOrPropertyAccess(InvocationStyle.SUPER,
sourceInfo, method, instance, methodNameRef, args);
}
private JsExpression getPrototypeQualifierViaLookup(JDeclaredType type, SourceInfo sourceInfo) {
if (closureCompilerFormatEnabled) {
return getPrototypeQualifierOf(type, type.getSourceInfo());
} else {
// Construct JCHSU.getPrototypeFor(type).polyname
// TODO(rluble): Ideally we would want to construct the inheritance chain the JS way and
// then we could do Type.prototype.polyname.call(this, ...). Currently prototypes do not
// have global names instead they are stuck into the prototypesByTypeId array.
return constructInvocation(sourceInfo, RuntimeConstants.RUNTIME_GET_CLASS_PROTOTYPE,
(JsExpression) transform(getRuntimeTypeReference(type)));
}
}
private JsExpression dispatchToJsFunction(JsExpression instance, JMethod method,
List<JsExpression> args, SourceInfo sourceInfo) {
return createInvocationOrPropertyAccess(
InvocationStyle.FUNCTION, sourceInfo, method, instance, null, args);
}
private JsExpression dispatchToInstanceMethod(JsExpression instance, JMethod method,
List<JsExpression> args, SourceInfo sourceInfo) {
JsNameRef reference = polymorphicNames.get(method).makeQualifiedRef(sourceInfo, instance);
return createInvocationOrPropertyAccess(
InvocationStyle.NORMAL, sourceInfo, method, instance, reference, args);
}
@Override
public JsNode transformMultiExpression(JMultiExpression multiExpression) {
if (multiExpression.isEmpty()) {
// the multi-expression was empty; use undefined
return JsRootScope.INSTANCE.getUndefined().makeRef(multiExpression.getSourceInfo());
}
List<JsExpression> exprs = transform(multiExpression.getExpressions());
JsExpression cur = null;
for (int i = 0; i < exprs.size(); ++i) {
JsExpression next = exprs.get(i);
cur = JsUtils.createCommaExpression(cur, next);
}
return cur;
}
@Override
public JsNode transformNameOf(JNameOf nameof) {
JsName name = names.get(nameof.getNode());
if (name == null) {
return JsRootScope.INSTANCE.getUndefined().makeRef(nameof.getSourceInfo());
}
return new JsNameOf(nameof.getSourceInfo(), name);
}
@Override
public JsNode transformNewInstance(JNewInstance newInstance) {
SourceInfo sourceInfo = newInstance.getSourceInfo();
JConstructor ctor = newInstance.getTarget();
JsName ctorName = names.get(ctor);
JsNameRef reference = ctor.isJsNative()
? createGlobalQualifier(ctor.getQualifiedJsName(), sourceInfo)
: ctorName.makeRef(sourceInfo);
List<JsExpression> arguments = transform(newInstance.getArgs());
if (newInstance.getClassType().isJsFunctionImplementation()) {
// Synthesize makeLambdaFunction(samMethodReference, constructorReference, ctorArguments)
// which will create the function instance and run the constructor on it.
// TODO(rluble): optimize the constructor call away if it is empty.
return constructJsFunctionObject(
sourceInfo,
newInstance.getClassType(),
ctorName,
reference,
new JsArrayLiteral(sourceInfo, arguments));
}
return JsUtils.createInvocationOrPropertyAccess(
InvocationStyle.NEWINSTANCE, sourceInfo, ctor, null, reference, arguments);
}
private JsExpression constructJsFunctionObject(SourceInfo sourceInfo, JClassType type,
JsName ctorName, JsNameRef ctorReference, JsExpression ctorArguments) {
// Foo.prototype.functionMethodName
JMethod jsFunctionMethod = getJsFunctionMethod(type);
JsNameRef funcNameRef = JsUtils.createQualifiedNameRef(sourceInfo,
ctorName, prototype, polymorphicNames.get(jsFunctionMethod));
// makeLambdaFunction(Foo.prototype.functionMethodName, new Foo(...))
return constructInvocation(sourceInfo, RuntimeConstants.RUNTIME_MAKE_LAMBDA_FUNCTION,
funcNameRef, ctorReference, ctorArguments);
}
private JMethod getJsFunctionMethod(JClassType type) {
for (JMethod method : type.getMethods()) {
if (method.isOrOverridesJsFunctionMethod()) {
return method;
}
}
throw new AssertionError("Should never reach here.");
}
@Override
public JsNode transformNumericEntry(JNumericEntry entry) {
return new JsNumericEntry(entry.getSourceInfo(), entry.getKey(), entry.getValue());
}
@Override
public JsNode transformParameter(JParameter parameter) {
assert !(currentMethod.isJsMethodVarargs() && parameter.isVarargs());
return new JsParameter(parameter.getSourceInfo(), names.get(parameter));
}
@Override
public JsNode transformParameterRef(JParameterRef parameterRef) {
return names.get(parameterRef.getTarget()).makeRef(parameterRef.getSourceInfo());
}
@Override
public JsNode transformPermutationDependentValue(JPermutationDependentValue dependentValue) {
throw new AssertionError("AST should not contain permutation dependent values at " +
"this point but contains " + dependentValue);
}
@Override
public JsNode transformPostfixOperation(JPostfixOperation expression) {
return new JsPostfixOperation(expression.getSourceInfo(), JavaToJsOperatorMap.get(expression.getOp()),
transform(expression.getArg()));
}
@Override
public JsNode transformPrefixOperation(JPrefixOperation expression) {
return new JsPrefixOperation(expression.getSourceInfo(),
JavaToJsOperatorMap.get(expression.getOp()), transform(expression.getArg()));
}
/**
* Embeds properties into permProps for easy access from JavaScript.
*/
private void embedBindingProperties() {
SourceInfo sourceInfo = SourceOrigin.UNKNOWN;
// Generates a list of lists of pairs: [[["key", "value"], ...], ...]
// The outermost list is indexed by soft permutation id. Each item represents
// a map from binding properties to their values, but is stored as a list of pairs
// for easy iteration.
JsArrayLiteral permutationProperties = new JsArrayLiteral(sourceInfo);
for (Map<String, String> propertyValueByPropertyName :
properties.findEmbeddedProperties(TreeLogger.NULL)) {
JsArrayLiteral entryList = new JsArrayLiteral(sourceInfo);
for (Entry<String, String> entry : propertyValueByPropertyName.entrySet()) {
JsArrayLiteral pair = new JsArrayLiteral(sourceInfo,
new JsStringLiteral(sourceInfo, entry.getKey()),
new JsStringLiteral(sourceInfo, entry.getValue()));
entryList.getExpressions().add(pair);
}
permutationProperties.getExpressions().add(entryList);
}
getGlobalStatements().add(
constructInvocation(sourceInfo, "ModuleUtils.setGwtProperty",
new JsStringLiteral(sourceInfo, "permProps"), permutationProperties).makeStmt());
}
@Override
public JsNode transformReturnStatement(JReturnStatement returnStatement) {
return new JsReturn(returnStatement.getSourceInfo(), transform(returnStatement.getExpr()));
}
@Override
public JsNode transformRunAsync(JRunAsync runAsync) {
return transform(runAsync.getRunAsyncCall());
}
@Override
public JsNode transformCastMap(JCastMap castMap) {
SourceInfo sourceInfo = castMap.getSourceInfo();
List<JsExpression> jsCastToTypes = transform(castMap.getCanCastToTypes());
return buildJsCastMapLiteral(jsCastToTypes, sourceInfo);
}
@Override
public JsNameRef transformJsniMethodRef(JsniMethodRef jsniMethodRef) {
JMethod method = jsniMethodRef.getTarget();
if (method.isJsNative()) {
// Construct Constructor.prototype.jsname or Constructor.
return createGlobalQualifier(method.getQualifiedJsName(), jsniMethodRef.getSourceInfo());
}
return names.get(method).makeRef(jsniMethodRef.getSourceInfo());
}
@Override
public JsArrayLiteral transformJsonArray(JsonArray jsonArray) {
JsArrayLiteral jsArrayLiteral = new JsArrayLiteral(jsonArray.getSourceInfo());
transformInto(jsonArray.getExpressions(), jsArrayLiteral.getExpressions());
return jsArrayLiteral;
}
@Override
public JsNode transformThisRef(JThisRef thisRef) {
return new JsThisRef(thisRef.getSourceInfo());
}
@Override
public JsNode transformThrowStatement(JThrowStatement throwStatement) {
return new JsThrow(throwStatement.getSourceInfo(), transform(throwStatement.getExpr()));
}
@Override
public JsNode transformTryStatement(JTryStatement tryStatement) {
JsTry jsTry = new JsTry(tryStatement.getSourceInfo());
jsTry.setTryBlock(transform(tryStatement.getTryBlock()));
int size = tryStatement.getCatchClauses().size();
assert (size < 2);
if (size == 1) {
JBlock block = tryStatement.getCatchClauses().get(0).getBlock();
JsCatch jsCatch = catchMap.get(block);
jsCatch.setBody(transform(block));
jsTry.getCatches().add(jsCatch);
}
JsBlock finallyBlock = transform(tryStatement.getFinallyBlock());
if (finallyBlock != null && finallyBlock.getStatements().size() > 0) {
jsTry.setFinallyBlock(finallyBlock);
}
return jsTry;
}
@Override
public JsNode transformUnsafeTypeCoercion(JUnsafeTypeCoercion unsafeTypeCoercion) {
return transform(unsafeTypeCoercion.getExpression());
}
@Override
public JsNode transformWhileStatement(JWhileStatement whileStatement) {
SourceInfo info = whileStatement.getSourceInfo();
JsWhile stmt = new JsWhile(info);
stmt.setCondition(transform(whileStatement.getTestExpr()));
stmt.setBody(jsEmptyIfNull(info, transform(whileStatement.getBody())));
return stmt;
}
public JsStatement jsEmptyIfNull(SourceInfo info, JsStatement statement) {
return statement != null ? statement : new JsEmpty(info);
}
private void insertInTopologicalOrder(JDeclaredType type,
Set<JDeclaredType> topologicallySortedSet) {
if (type == null || topologicallySortedSet.contains(type) || program.isReferenceOnly(type)) {
return;
}
insertInTopologicalOrder(type.getSuperClass(), topologicallySortedSet);
for (JInterfaceType intf : type.getImplements()) {
if (program.typeOracle.isInstantiatedType(type)) {
insertInTopologicalOrder(intf, topologicallySortedSet);
}
}
topologicallySortedSet.add(type);
}
@Override
public JsNode transformProgram(JProgram program) {
// Handle the visiting here as we need to slightly change the order.
// 1.1 (preamble) Immortal code gentypes.
// 1.2 (preamble) Classes in the preamble, i.e. all the classes that are needed
// to support creation of class literals (reachable through Class.createFor* ).
// 1.3 (preamble) Class literals for classes in the preamble.
// 2. (body) Normal classes, each with its corresponding class literal (if live).
// 3. (epilogue) Code to start the execution of the program (gwtOnLoad, etc).
Set<JDeclaredType> preambleTypes = generatePreamble(program);
if (incremental) {
// Record the names of preamble types so that it's possible to invalidate caches when the
// preamble types are known to have become stale.
if (!minimalRebuildCache.hasPreambleTypeNames()) {
Set<String> preambleTypeNames = Sets.newHashSet();
for (JDeclaredType preambleType : preambleTypes) {
preambleTypeNames.add(preambleType.getName());
}
minimalRebuildCache.setPreambleTypeNames(logger, preambleTypeNames);
}
}
// Sort normal types according to superclass relationship.
Set<JDeclaredType> topologicallySortedBodyTypes = Sets.newLinkedHashSet();
for (JDeclaredType type : program.getModuleDeclaredTypes()) {
insertInTopologicalOrder(type, topologicallySortedBodyTypes);
}
// Remove all preamble types that might have been inserted here.
topologicallySortedBodyTypes.removeAll(preambleTypes);
// Iterate over each type in the right order.
markPosition("Program", Type.PROGRAM_START);
for (JDeclaredType type : topologicallySortedBodyTypes) {
markPosition(type.getName(), Type.CLASS_START);
transform(type);
maybeGenerateClassLiteral(type);
installClassLiterals(Arrays.asList(type));
markPosition(type.getName(), Type.CLASS_END);
}
markPosition("Program", Type.PROGRAM_END);
generateEpilogue();
// All done, do not visit children.
return null;
}
private Set<JDeclaredType> generatePreamble(JProgram program) {
// Reserve the "_" identifier.
JsVars vars = new JsVars(jsProgram.getSourceInfo());
vars.add(new JsVar(jsProgram.getSourceInfo(), globalTemp));
addVarsIfNotEmpty(vars);
// Generate immortal types in the preamble.
generateImmortalTypes(vars);
// Perform necessary polyfills.
addTypeDefinitionStatement(
program.getIndexedType(RuntimeConstants.RUNTIME),
constructInvocation(program.getSourceInfo(), RuntimeConstants.RUNTIME_BOOTSTRAP)
.makeStmt());
Set<JDeclaredType> alreadyProcessed =
Sets.<JDeclaredType>newLinkedHashSet(program.immortalCodeGenTypes);
alreadyProcessed.add(program.getTypeClassLiteralHolder());
alreadyRan.addAll(alreadyProcessed);
List<JDeclaredType> classLiteralSupportClasses =
computeClassLiteralsSupportClasses(program, alreadyProcessed);
// Make sure immortal classes are not doubly processed.
classLiteralSupportClasses.removeAll(alreadyProcessed);
for (JDeclaredType type : classLiteralSupportClasses) {
transform(type);
}
generateClassLiterals(classLiteralSupportClasses);
installClassLiterals(classLiteralSupportClasses);
Set<JDeclaredType> preambleTypes = Sets.newLinkedHashSet(alreadyProcessed);
preambleTypes.addAll(classLiteralSupportClasses);
return preambleTypes;
}
private JsNameRef transformIntoLabelReference(SourceInfo info, JLabel label) {
if (label == null) {
return null;
}
return ((JsLabel) transform(label)).getName().makeRef(info);
}
private void installClassLiterals(List<JDeclaredType> classLiteralTypesToInstall) {
if (!closureCompilerFormatEnabled) {
// let createForClass() install them until a follow on CL
// TODO(cromwellian) remove after approval from rluble in follow up CL
return;
}
for (JDeclaredType type : classLiteralTypesToInstall) {
if (shouldNotEmitTypeDefinition(type)) {
continue;
}
JsNameRef classLiteralRef = createClassLiteralReference(type);
if (classLiteralRef == null) {
continue;
}
SourceInfo sourceInfo = type.getSourceInfo();
JsExpression protoRef = getPrototypeQualifierOf(type, sourceInfo);
JsNameRef clazzField =
getIndexedFieldJsName(RuntimeConstants.OBJECT_CLAZZ).makeRef(sourceInfo);
clazzField.setQualifier(protoRef);
JsExprStmt stmt = createAssignment(clazzField, classLiteralRef).makeStmt();
addTypeDefinitionStatement(type, stmt);
}
}
private boolean shouldNotEmitTypeDefinition(JDeclaredType type) {
// Interfaces, Unboxed Types, JSOs, Native Types, JsFunction, and uninstantiated types
// Do not have vtables/prototype setup
return type instanceof JInterfaceType && !closureCompilerFormatEnabled
|| program.isRepresentedAsNativeJsPrimitive(type)
|| !program.typeOracle.isInstantiatedType(type)
|| type.isJsoType()
|| type.isJsNative()
|| type.isJsFunction();
}
private List<JDeclaredType> computeClassLiteralsSupportClasses(JProgram program,
Set<JDeclaredType> alreadyProcessedTypes) {
if (program.isReferenceOnly(program.getIndexedType("Class"))) {
return Collections.emptyList();
}
// Include in the preamble all classes that are reachable for Class.createForClass,
// Class.createForInterface
SortedSet<JDeclaredType> reachableClasses =
computeReachableTypes(METHODS_PROVIDED_BY_PREAMBLE);
assert !incremental || checkCoreModulePreambleComplete(program,
program.getTypeClassLiteralHolder().getClinitMethod());
Set<JDeclaredType> orderedPreambleClasses = Sets.newLinkedHashSet();
for (JDeclaredType type : reachableClasses) {
if (alreadyProcessedTypes.contains(type)) {
continue;
}
insertInTopologicalOrder(type, orderedPreambleClasses);
}
// TODO(rluble): The set of preamble types might be overly large, in particular will include
// JSOs that need clinit. This is due to {@link ControlFlowAnalyzer} making all JSOs live if
// there is a cast to that type anywhere in the program. See the use of
// {@link JTypeOracle.getInstantiatedJsoTypesViaCast} in the constructor.
return Lists.newArrayList(orderedPreambleClasses);
}
/**
* Check that in modular compiles the preamble is complete.
* <p>
* In modular compiles the preamble has to include code for creating all 4 types of class
* literals.
*/
private boolean checkCoreModulePreambleComplete(JProgram program,
JMethod classLiteralInitMethod) {
final Set<JMethod> calledMethods = Sets.newHashSet();
new JVisitor() {
@Override
public void endVisit(JMethodCall x, Context ctx) {
calledMethods.add(x.getTarget());
}
}.accept(classLiteralInitMethod);
for (String createForMethodName : METHODS_PROVIDED_BY_PREAMBLE) {
if (!calledMethods.contains(program.getIndexedMethod(createForMethodName))) {
return false;
}
}
return true;
}
/**
* Computes the set of types whose methods or fields are reachable from {@code methods}.
*/
private SortedSet<JDeclaredType> computeReachableTypes(Iterable<String> methodNames) {
ControlFlowAnalyzer cfa = new ControlFlowAnalyzer(program);
for (String methodName : methodNames) {
JMethod method = program.getIndexedMethodOrNull(methodName);
// Only traverse it if it has not been pruned.
if (method != null) {
cfa.traverseFrom(method);
}
}
// Get the list of enclosing classes that were not excluded.
SortedSet<JDeclaredType> reachableTypes =
ImmutableSortedSet.copyOf(HasName.BY_NAME_COMPARATOR,
Iterables.filter(
Iterables.transform(cfa.getLiveFieldsAndMethods(),
new Function<JNode, JDeclaredType>() {
@Override
public JDeclaredType apply(JNode member) {
if (member instanceof JMethod) {
return ((JMethod) member).getEnclosingType();
} else if (member instanceof JField) {
return ((JField) member).getEnclosingType();
} else {
assert member instanceof JParameter || member instanceof JLocal;
// Discard locals and parameters, only need the enclosing instances of reachable
// fields and methods.
return null;
}
}
}), Predicates.notNull()));
return reachableTypes;
}
private JsExpression generateAbstractMethodDefinition(JMethod method) {
return (closureCompilerFormatEnabled) ?
JsUtils.createQualifiedNameRef(GOOG_ABSTRACT_METHOD, method.getSourceInfo()) : null;
}
private void generateEpilogue() {
generateRemainingClassLiterals();
// add all @JsExport assignments
generateExports();
// Generate entry methods. Needs to be after class literal insertion since class literal will
// be referenced by runtime rebind and property provider bootstrapping.
setupGwtOnLoad();
embedBindingProperties();
}
private void generateRemainingClassLiterals() {
if (!incremental) {
// Emit classliterals that are references but whose classes are not live.
generateClassLiterals(Iterables.filter(classLiteralDeclarationsByType.keySet(),
Predicates.not(Predicates.<JType>in(alreadyRan))));
return;
}
// In incremental, class literal references to class literals that were not generated
// as part of the current compile have to be from reference only classes.
assert FluentIterable.from(classLiteralDeclarationsByType.keySet())
.filter(Predicates.instanceOf(JDeclaredType.class))
.filter(Predicates.not(Predicates.<JType>in(alreadyRan)))
.filter(
new Predicate<JType>() {
@Override
public boolean apply(JType type) {
return !program.isReferenceOnly((JDeclaredType) type);
}
})
.isEmpty();
// In incremental only the class literals for the primitive types should be part of the
// epilogue.
generateClassLiterals(JPrimitiveType.types);
}
private void generateClassLiterals(Iterable<? extends JType> orderedTypes) {
for (JType type : orderedTypes) {
maybeGenerateClassLiteral(type);
}
}
private void generateExports() {
Map<String, Object> exportedMembersByExportName = new TreeMap<String, Object>();
Set<JDeclaredType> hoistedClinits = Sets.newHashSet();
JsInteropExportsGenerator exportGenerator =
closureCompilerFormatEnabled
? new ClosureJsInteropExportsGenerator(getGlobalStatements(), names)
: new DefaultJsInteropExportsGenerator(getGlobalStatements(), globalTemp,
getIndexedMethodJsName(RuntimeConstants.RUNTIME_PROVIDE));
// Gather exported things in JsNamespace order.
for (JDeclaredType type : program.getDeclaredTypes()) {
if (type.isJsNative()) {
// JsNative types have no implementation and so shouldn't export anything.
continue;
}
if (type.isJsType()) {
exportedMembersByExportName.put(type.getQualifiedJsName(), type);
}
for (JMember member : type.getMembers()) {
if (member.isJsInteropEntryPoint()) {
if (member.getJsMemberType() == JsMemberType.PROPERTY && !member.isFinal()) {
// TODO(goktug): Remove the warning when we export via Object.defineProperty
logger.log(
TreeLogger.Type.WARN,
"Exporting effectively non-final field "
+ member.getQualifiedName()
+ ". Due to the way exporting works, the value of the"
+ " exported field will not be reflected across Java/JavaScript border.");
}
exportedMembersByExportName.put(member.getQualifiedJsName(), member);
}
}
}
// Output the exports.
for (Object exportedEntity : exportedMembersByExportName.values()) {
if (exportedEntity instanceof JDeclaredType) {
exportGenerator.exportType((JDeclaredType) exportedEntity);
} else {
JMember member = (JMember) exportedEntity;
maybeHoistClinit(hoistedClinits, member);
exportGenerator.exportMember(member, names.get(member).makeRef(member.getSourceInfo()));
}
}
}
private void maybeHoistClinit(Set<JDeclaredType> hoistedClinits, JMember member) {
JDeclaredType enclosingType = member.getEnclosingType();
if (hoistedClinits.contains(enclosingType)) {
return;
}
JsInvocation clinitCall = member instanceof JMethod ? maybeCreateClinitCall((JMethod) member)
: maybeCreateClinitCall((JField) member);
if (clinitCall != null) {
hoistedClinits.add(enclosingType);
getGlobalStatements().add(clinitCall.makeStmt());
}
}
@Override
public JsFunction transformJsniMethodBody(JsniMethodBody jsniMethodBody) {
final Map<String, JNode> nodeByJsniReference = Maps.newHashMap();
for (JsniClassLiteral ref : jsniMethodBody.getClassRefs()) {
nodeByJsniReference.put(ref.getIdent(), ref.getField());
}
for (JsniFieldRef ref : jsniMethodBody.getJsniFieldRefs()) {
nodeByJsniReference.put(ref.getIdent(), ref.getField());
}
for (JsniMethodRef ref : jsniMethodBody.getJsniMethodRefs()) {
nodeByJsniReference.put(ref.getIdent(), ref.getTarget());
}
final JsFunction function = jsniMethodBody.getFunc();
// replace all JSNI idents with a real JsName now that we know it
new JsModVisitor() {
/**
* Marks a ctor that is a direct child of an invocation. Instead of
* replacing the ctor with a tear-off, we replace the invocation with a
* new operation.
*/
private JsNameRef dontReplaceCtor;
@Override
public void endVisit(JsInvocation x, JsContext ctx) {
// TODO(rluble): this fixup should be done during the initial JSNI processing in
// GwtAstBuilder.JsniReferenceCollector.
if (!(x.getQualifier() instanceof JsNameRef)) {
// If the invocation does not have a name as a qualifier (it might be an expression).
return;
}
JsNameRef ref = (JsNameRef) x.getQualifier();
if (!ref.isJsniReference()) {
// The invocation is not to a JSNI method.
return;
}
// Only constructors reach this point, all other JSNI references in the method body
// would have already been replaced at endVisit(JsNameRef).
// Replace invocation to ctor with a new op.
String ident = ref.getIdent();
assert ref.getQualifier() == null;
JConstructor constructor = (JConstructor) nodeByJsniReference.get(ident);
JsNameRef constructorJsName = createStaticReference(constructor, x.getSourceInfo());
ctx.replaceMe(new JsNew(x.getSourceInfo(), constructorJsName, x.getArguments()));
}
@Override
public void endVisit(JsNameRef x, JsContext ctx) {
if (!x.isJsniReference()) {
return;
}
String ident = x.getIdent();
JNode node = nodeByJsniReference.get(ident);
assert (node != null);
if (node instanceof JField) {
JField field = (JField) node;
if (field.isStatic() && field.isJsNative()) {
ctx.replaceMe(createQualifiedNameRef(field.getQualifiedJsName(), x.getSourceInfo()));
return;
}
JsName jsName = names.get(field);
assert (jsName != null);
x.resolve(jsName);
// See if we need to add a clinit call to a static field ref
JsInvocation clinitCall = maybeCreateClinitCall(field);
if (clinitCall != null) {
JsExpression commaExpr = JsUtils.createCommaExpression(clinitCall, x);
ctx.replaceMe(commaExpr);
}
} else if (node instanceof JConstructor) {
if (x == dontReplaceCtor) {
// Do nothing, parent will handle.
} else {
// Replace with a local closure function.
// function(a,b,c){return new Obj(a,b,c);}
JConstructor constructor = (JConstructor) node;
SourceInfo info = x.getSourceInfo();
JsNameRef constructorJsNameRef = createStaticReference(constructor, info);
JsFunction anonymousFunction = new JsFunction(info, function.getScope());
for (JParameter p : constructor.getParams()) {
JsName name = anonymousFunction.getScope().declareName(p.getName());
anonymousFunction.getParameters().add(new JsParameter(info, name));
}
JsNew jsNew = new JsNew(info, constructorJsNameRef);
for (JsParameter p : anonymousFunction.getParameters()) {
jsNew.getArguments().add(p.getName().makeRef(info));
}
anonymousFunction.setBody(new JsBlock(info));
anonymousFunction.getBody().getStatements().add(new JsReturn(info, jsNew));
ctx.replaceMe(anonymousFunction);
}
} else {
JMethod method = (JMethod) node;
if (!method.needsDynamicDispatch() && method.isJsNative()) {
ctx.replaceMe(createGlobalQualifier(method.getQualifiedJsName(), x.getSourceInfo()));
return;
}
if (x.getQualifier() == null) {
JsName jsName = names.get(method);
assert (jsName != null);
x.resolve(jsName);
} else {
JsName jsName = polymorphicNames.get(method);
if (jsName == null) {
// this can occur when JSNI references an instance method on a
// type that was never actually instantiated.
jsName = getIndexedMethodJsName(RuntimeConstants.RUNTIME_EMPTY_METHOD);
}
x.resolve(jsName);
}
}
}
@Override
public boolean visit(JsInvocation x, JsContext ctx) {
if (x.getQualifier() instanceof JsNameRef) {
dontReplaceCtor = (JsNameRef) x.getQualifier();
}
return true;
}
}.accept(function);
return function;
}
@Override
public JsStatement transformSwitchStatement(JSwitchStatement switchStatement) {
/*
* What a pain.. JSwitchStatement and JsSwitch are modeled completely
* differently. Here we try to resolve those differences.
*/
JsSwitch jsSwitch = new JsSwitch(switchStatement.getSourceInfo());
jsSwitch.setExpr(transform(switchStatement.getExpr()));
List<JStatement> bodyStmts = switchStatement.getBody().getStatements();
List<JsStatement> curStatements = null;
for (JStatement stmt : bodyStmts) {
if (stmt instanceof JCaseStatement) {
// create a new switch member
JsSwitchMember switchMember = transform((JNode) stmt);
jsSwitch.getCases().add(switchMember);
curStatements = switchMember.getStmts();
} else {
// add to statements for current case
assert (curStatements != null);
JsStatement newStmt = transform(stmt);
if (newStmt != null) {
// Empty JDeclarationStatement produces a null
curStatements.add(newStmt);
}
}
}
return jsSwitch;
}
private JsExpression buildJsCastMapLiteral(List<JsExpression> runtimeTypeIdLiterals,
SourceInfo sourceInfo) {
if (JjsUtils.closureStyleLiteralsNeeded(incremental, closureCompilerFormatEnabled)) {
return buildClosureStyleCastMapFromArrayLiteral(runtimeTypeIdLiterals, sourceInfo);
}
JsNumberLiteral one = new JsNumberLiteral(sourceInfo, 1);
JsObjectLiteral.Builder objectLiteralBuilder = JsObjectLiteral.builder(sourceInfo)
.setInternable();
for (JsExpression runtimeTypeIdLiteral : runtimeTypeIdLiterals) {
objectLiteralBuilder.add(runtimeTypeIdLiteral, one);
}
return objectLiteralBuilder.build();
}
private JsExpression buildClosureStyleCastMapFromArrayLiteral(
List<JsExpression> runtimeTypeIdLiterals, SourceInfo sourceInfo) {
/*
* goog.object.createSet('foo', 'bar', 'baz') is optimized by closure compiler into
* {'foo': !0, 'bar': !0, baz: !0}
*/
JsNameRef createSet = new JsNameRef(sourceInfo, GOOG_OBJECT_CREATE_SET);
JsInvocation jsInvocation = new JsInvocation(sourceInfo, createSet);
for (JsExpression expr : runtimeTypeIdLiterals) {
jsInvocation.getArguments().add(expr);
}
return jsInvocation;
}
private void checkForDuplicateMethods(JDeclaredType type) {
// Sanity check to see that all methods are uniquely named.
List<JMethod> methods = type.getMethods();
Set<String> methodSignatures = Sets.newHashSet();
for (JMethod method : methods) {
String sig = method.getSignature();
if (methodSignatures.contains(sig)) {
throw new InternalCompilerException("Signature collision in Type " + type.getName()
+ " for method " + sig);
}
methodSignatures.add(sig);
}
}
private JsNameRef createStaticReference(JMember member, SourceInfo sourceInfo) {
assert !member.needsDynamicDispatch();
return member.isJsNative()
? createGlobalQualifier(member.getQualifiedJsName(), sourceInfo)
: names.get(member).makeRef(sourceInfo);
}
private void emitFields(JDeclaredType type) {
JsVars vars = new JsVars(type.getSourceInfo());
for (JField field : type.getFields()) {
if (field.isJsNative()) {
// Nothing to output for native fields.
continue;
}
JsExpression initializer = null;
// if we need an initial value, create an assignment
if (initializeAtTopScope(field)) {
// setup the constant value
initializer = transform(field.getLiteralInitializer());
} else if (field.getType().getDefaultValue() == JNullLiteral.INSTANCE) {
// Fields whose default value is null are left uninitialized and will
// have a JS value of undefined.
} else {
// setup the default value, see Issue 380
initializer = transform(field.getType().getDefaultValue());
}
JsName name = names.get(field);
if (field.isStatic()) {
// setup a var for the static
JsVar var = new JsVar(type.getSourceInfo(), name);
var.setInitExpr(initializer);
vars.add(var);
} else if (initializer != null) {
// Instance field initilized at top.
JsNameRef fieldRef =
name.makeQualifiedRef(field.getSourceInfo(), getPrototypeQualifierOf(field));
addTypeDefinitionStatement(type, createAssignment(fieldRef, initializer).makeStmt());
}
}
addVarsIfNotEmpty(vars);
}
private void emitStaticMethods(JDeclaredType type) {
// declare all methods into the global scope
for (JMethod method : type.getMethods()) {
if (method.needsDynamicDispatch()) {
continue;
}
JsFunction function = transform(method);
if (function == null) {
continue;
}
if (JProgram.isClinit(method)) {
handleClinit(type, function);
}
emitMethodImplementation(method,
function.getName().makeRef(function.getSourceInfo()), function.makeStmt());
}
}
private JsExpression generateCastableTypeMap(JDeclaredType type) {
JCastMap castMap = program.getCastMap(type);
JsName castableTypeMapName = getIndexedFieldJsName(RuntimeConstants.OBJECT_CASTABLE_TYPE_MAP);
if (castMap != null && castableTypeMapName != null) {
return transform(castMap);
}
return JsObjectLiteral.EMPTY;
}
private JField getClassLiteralField(JType type) {
JDeclarationStatement decl = classLiteralDeclarationsByType.get(type);
if (decl == null) {
return null;
}
return (JField) decl.getVariableRef().getTarget();
}
private void maybeGenerateClassLiteral(JType type) {
JField field = getClassLiteralField(type);
if (field == null) {
return;
}
// TODO(rluble): refactor so that all output related to a class is decided together.
if (type != null && type instanceof JDeclaredType
&& program.isReferenceOnly((JDeclaredType) type)) {
// Only generate class literals for classes in the current module.
// TODO(rluble): In separate compilation some class literals will be duplicated, which if
// not done with care might violate java semantics of getClass(). There are class literals
// for primitives and arrays. Currently, because they will be assigned to the same field
// the one defined later will be the one used and Java semantics are preserved.
return;
}
JsVars vars = new JsVars(jsProgram.getSourceInfo());
JsName jsName = names.get(field);
JsExpression classLiteralObject = transform(field.getInitializer());
JsVar var = new JsVar(field.getSourceInfo(), jsName);
var.setInitExpr(classLiteralObject);
vars.add(var);
addVarsIfNotEmpty(vars);
}
private JsNameRef createClassLiteralReference(JType type) {
JField field = getClassLiteralField(type);
if (field == null) {
return null;
}
JsName jsName = names.get(field);
return jsName.makeRef(type.getSourceInfo());
}
private void generateTypeSetup(JDeclaredType type) {
if (program.isRepresentedAsNativeJsPrimitive(type)
&& program.typeOracle.isInstantiatedType(type)) {
setupCastMapForUnboxedType(type,
program.getRepresentedAsNativeTypesDispatchMap().get(type).getCastMapField());
return;
}
if (shouldNotEmitTypeDefinition(type)) {
return;
}
generateClassDefinition(type);
generatePrototypeDefinitions(type);
maybeGenerateObjectMethodsAliases(type);
}
private void markPosition(String name, Type type) {
getGlobalStatements().add(new JsPositionMarker(SourceOrigin.UNKNOWN, name, type));
}
/**
* Sets up gwtOnLoad bootstrapping code. Unusually, the created code is executed as part of
* source loading and runs in the global scope (not inside of any function scope).
*/
private void setupGwtOnLoad() {
/**
* <pre>
* var $entry = Impl.registerEntry();
* var gwtOnLoad = ModuleUtils.gwtOnLoad();
* ModuleUtils.addInitFunctions(init1, init2,...)
* </pre>
*/
final SourceInfo sourceInfo = SourceOrigin.UNKNOWN;
// var $entry = ModuleUtils.registerEntry();
JsStatement entryVars = constructFunctionCallStatement(
topScope.declareName("$entry"), "ModuleUtils.registerEntry");
getGlobalStatements().add(entryVars);
// var gwtOnLoad = ModuleUtils.gwtOnLoad;
JsName gwtOnLoad = topScope.findExistingUnobfuscatableName("gwtOnLoad");
JsVar varGwtOnLoad = new JsVar(sourceInfo, gwtOnLoad);
varGwtOnLoad.setInitExpr(createAssignment(gwtOnLoad.makeRef(sourceInfo),
getIndexedMethodJsName(RuntimeConstants.MODULE_UTILS_GWT_ON_LOAD).makeRef(sourceInfo)));
getGlobalStatements().add(new JsVars(sourceInfo, varGwtOnLoad));
// ModuleUtils.addInitFunctions(init1, init2,...)
List<JsExpression> arguments = Lists.newArrayList();
for (JMethod entryPointMethod : program.getEntryMethods()) {
JsFunction entryFunction = getJsFunctionFor(entryPointMethod);
arguments.add(entryFunction.getName().makeRef(sourceInfo));
}
JsStatement createGwtOnLoadFunctionCall =
constructInvocation("ModuleUtils.addInitFunctions", arguments).makeStmt();
getGlobalStatements().add(createGwtOnLoadFunctionCall);
}
/**
* Creates a (var) assignment a statement for a function call to an indexed function.
*/
private JsStatement constructFunctionCallStatement(JsName assignToVariableName,
String indexedFunctionName, JsExpression... args) {
return constructFunctionCallStatement(assignToVariableName, indexedFunctionName,
Arrays.asList(args));
}
/**
* Creates a (var) assignment a statement for a function call to an indexed function.
*/
private JsStatement constructFunctionCallStatement(JsName assignToVariableName,
String indexedFunctionName, List<JsExpression> args) {
SourceInfo sourceInfo = SourceOrigin.UNKNOWN;
JsInvocation invocation = constructInvocation(indexedFunctionName, args);
JsVar var = new JsVar(sourceInfo, assignToVariableName);
var.setInitExpr(invocation);
JsVars entryVars = new JsVars(sourceInfo);
entryVars.add(var);
return entryVars;
}
/**
* Constructs an invocation for an indexed function.
*/
private JsInvocation constructInvocation(SourceInfo sourceInfo,
String indexedFunctionName, JsExpression... args) {
return constructInvocation(sourceInfo, indexedFunctionName, Arrays.asList(args));
}
/**
* Constructs an invocation for an indexed function.
*/
private JsInvocation constructInvocation(String indexedFunctionName,
List<JsExpression> args) {
SourceInfo sourceInfo = SourceOrigin.UNKNOWN;
return constructInvocation(sourceInfo, indexedFunctionName, args);
}
/**
* Constructs an invocation for an indexed function.
*/
private JsInvocation constructInvocation(SourceInfo sourceInfo,
String indexedFunctionName, List<JsExpression> args) {
JsName functionToInvoke = getIndexedMethodJsName(indexedFunctionName);
return new JsInvocation(sourceInfo, functionToInvoke.makeRef(sourceInfo), args);
}
private void generateImmortalTypes(JsVars globals) {
List<JClassType> immortalTypesReversed = Lists.reverse(program.immortalCodeGenTypes);
// visit in reverse order since insertions start at head
for (JClassType x : immortalTypesReversed) {
// Don't generate JS for referenceOnly types.
if (program.isReferenceOnly(x)) {
continue;
}
// should not be pruned
assert x.getMethods().size() > 0;
// insert all static methods
for (JMethod method : x.getMethods()) {
/*
* Skip virtual methods and constructors. Even in cases where there is no constructor
* defined, the compiler will synthesize a default constructor which invokes
* a synthesized $init() method. We must skip both of these inserted methods.
*/
if (method.needsDynamicDispatch() || method instanceof JConstructor
|| doesNotHaveConcreteImplementation(method)) {
continue;
}
// add after var declaration, but before everything else
JsFunction function = transform(method);
assert function.getName() != null;
addMethodDefinitionStatement(1, method, function.makeStmt());
}
// insert fields into global var declaration
for (JField field : x.getFields()) {
assert field.isStatic() : "'" + field.getName()
+ "' is not static. Only static fields are allowed on immortal types";
assert field.getInitializer() == field.getLiteralInitializer() : "'" + field.getName()
+ "' is not initilialized to a literal."
+ " Only literal initializers are allowed on immortal types";
JsVar var = new JsVar(x.getSourceInfo(), names.get(field));
var.setInitExpr(transform(field.getLiteralInitializer()));
globals.add(var);
}
}
}
private void generateCallToDefineClass(JClassType type, List<JsNameRef> constructorArgs) {
JClassType superClass = type.getSuperClass();
JExpression superTypeId = (superClass == null) ? JNullLiteral.INSTANCE :
getRuntimeTypeReference(superClass);
String jsPrototype = getSuperPrototype(type);
List<JsExpression> defineClassArguments = Lists.newArrayList();
defineClassArguments.add(transform(getRuntimeTypeReference(type)));
defineClassArguments.add(jsPrototype == null ? transform(superTypeId) :
createGlobalQualifier(jsPrototype, type.getSourceInfo()));
defineClassArguments.add(generateCastableTypeMap(type));
defineClassArguments.addAll(constructorArgs);
// Runtime.defineClass(typeId, superTypeId, castableMap, constructors)
JsStatement defineClassStatement = constructInvocation(type.getSourceInfo(),
RuntimeConstants.RUNTIME_DEFINE_CLASS, defineClassArguments).makeStmt();
addTypeDefinitionStatement(type, defineClassStatement);
maybeCopyJavaLangObjectProperties(
type,
getPrototypeQualifierViaLookup(program.getTypeJavaLangObject(), type.getSourceInfo()),
globalTemp.makeRef(type.getSourceInfo()));
}
private void maybeCopyJavaLangObjectProperties(
JDeclaredType type, JsExpression javaLangObjectPrototype, JsExpression toPrototype) {
if (getSuperPrototype(type) != null && !type.isJsFunctionImplementation()) {
JsStatement statement =
constructInvocation(
type.getSourceInfo(),
RuntimeConstants.RUNTIME_COPY_OBJECT_PROPERTIES,
javaLangObjectPrototype,
toPrototype
).makeStmt();
addTypeDefinitionStatement(type, statement);
}
}
private String getSuperPrototype(JDeclaredType type) {
if (type.isJsFunctionImplementation()) {
return "Function";
}
JClassType superClass = type.getSuperClass();
if (superClass != null && superClass.isJsNative()) {
return superClass.getQualifiedJsName();
}
return null;
}
private void generateClassDefinition(JDeclaredType type) {
assert !program.isRepresentedAsNativeJsPrimitive(type);
if (closureCompilerFormatEnabled) {
generateClosureTypeDefinition(type);
} else {
generateJsClassDefinition((JClassType) type);
}
}
/*
* Class definition for regular output looks like:
*
* defineClass(id, superId, castableTypeMap, ctor1, ctor2, ctor3);
* _.method1 = function() { ... }
* _.method2 = function() { ... }
*/
private void generateJsClassDefinition(JClassType classType) {
// Add constructors as varargs to define class.
List<JsNameRef> constructorArgs = Lists.newArrayList();
for (JMethod method : getPotentiallyAliveConstructors(classType)) {
constructorArgs.add(names.get(method).makeRef(classType.getSourceInfo()));
}
// defineClass(..., Ctor1, Ctor2, ...)
generateCallToDefineClass(classType, constructorArgs);
}
/*
* Class definition for closure output looks like:
*
* function ClassName() {}
* ClassName.prototype.method1 = function() { ... };
* ClassName.prototype.method2 = function() { ... };
* ClassName.prototype.castableTypeMap = {...}
* ClassName.prototype.___clazz = classLit;
* function Ctor1() {}
* function Ctor2() {}
*
* goog$inherits(Ctor1, ClassName);
* goog$inherits(Ctor2, ClassName);
*
* The primary change is to make the prototype assignment look like regular closure code to help
* the compiler disambiguate which methods belong to which type. Elimination of defineClass()
* makes the setup more transparent and eliminates a global table holding a reference to
* every prototype.
*/
private void generateClosureTypeDefinition(JDeclaredType type) {
// function ClassName(){}
JsName classVar = declareSynthesizedClosureConstructor(type);
generateInlinedDefineClass(type, classVar);
/*
* Closure style prefers 1 single ctor per type. To model this without radical changes,
* we simply model each concrete ctor as a subtype. This works because GWT doesn't use the
* native instanceof operator. So for example, class A() { A(int type){}, A(String s){} }
* becomes (pseudo code):
*
* function A() {}
* A.prototype.method = ...
*
* function A_int(x) {}
* function A_String(s) {}
* goog$inherits(A_int, A);
* goog$inherits(A_string, A);
*
*/
for (JMethod method : getPotentiallyAliveConstructors(type)) {
SourceInfo typeSourceInfo = type.getSourceInfo();
JsNameRef googInherits = JsUtils.createQualifiedNameRef(GOOG_INHERITS, typeSourceInfo);
SourceInfo methodSourceInfo = method.getSourceInfo();
JsExprStmt callGoogInherits = new JsInvocation(typeSourceInfo, googInherits,
names.get(method).makeRef(methodSourceInfo),
names.get(method.getEnclosingType()).makeRef(methodSourceInfo)).makeStmt();
addMethodDefinitionStatement(method, callGoogInherits);
}
}
/**
* Does everything JCHSU.defineClass does, but inlined into global statements. Roughly
* parallels argument order of generateCallToDefineClass.
*/
private void generateInlinedDefineClass(JDeclaredType type, JsName classVar) {
if (type instanceof JInterfaceType) {
return;
}
JClassType superClass = type.getSuperClass();
// check if there's an overriding prototype
String jsPrototype = getSuperPrototype(type);
SourceInfo info = type.getSourceInfo();
JsNameRef parentCtor = jsPrototype != null ?
createGlobalQualifier(jsPrototype, info) :
superClass != null ?
names.get(superClass).makeRef(info) :
null;
if (parentCtor != null) {
JsNameRef googInherits = JsUtils.createQualifiedNameRef(GOOG_INHERITS, info);
// Use goog$inherits(ChildCtor, ParentCtor) to setup inheritance
JsExprStmt callGoogInherits = new JsInvocation(info, googInherits,
classVar.makeRef(info), parentCtor).makeStmt();
addTypeDefinitionStatement(type, callGoogInherits);
}
if (type == program.getTypeJavaLangObject()) {
setupTypeMarkerOnJavaLangObjectPrototype(type);
}
// inline assignment of castableTypeMap field instead of using defineClass()
setupCastMapOnPrototype(type);
maybeCopyJavaLangObjectProperties(
type,
getPrototypeQualifierOf(program.getTypeJavaLangObject(), info),
getPrototypeQualifierOf(type, info));
}
private void setupCastMapOnPrototype(JDeclaredType type) {
JsExpression castMap = generateCastableTypeMap(type);
generatePrototypeAssignmentForJavaField(type, "Object.castableTypeMap", castMap);
}
private void setupTypeMarkerOnJavaLangObjectPrototype(JDeclaredType type) {
JsName typeMarkerMethod = getIndexedMethodJsName(RuntimeConstants.RUNTIME_TYPE_MARKER_FN);
generatePrototypeAssignmentForJavaField(type, RuntimeConstants.OBJECT_TYPEMARKER,
typeMarkerMethod.makeRef(type.getSourceInfo()));
}
private void generatePrototypeAssignmentForJavaField(JDeclaredType type, String javaField,
JsExpression rhs) {
SourceInfo sourceInfo = type.getSourceInfo();
JsNameRef protoRef = getPrototypeQualifierOf(type, sourceInfo);
JsNameRef fieldRef = getIndexedFieldJsName(javaField).makeQualifiedRef(sourceInfo, protoRef);
addTypeDefinitionStatement(type, createAssignment(fieldRef, rhs).makeStmt());
}
private void addMethodDefinitionStatement(JMethod method,
JsExprStmt methodDefinitionStatement) {
getGlobalStatements().add(methodDefinitionStatement);
methodByGlobalStatement.put(methodDefinitionStatement, method);
}
private void addMethodDefinitionStatement(int position, JMethod method,
JsExprStmt methodDefinitionStatement) {
getGlobalStatements().add(position, methodDefinitionStatement);
methodByGlobalStatement.put(methodDefinitionStatement, method);
}
private void addTypeDefinitionStatement(JDeclaredType x, JsStatement statement) {
getGlobalStatements().add(statement);
javaTypeByGlobalStatement.put(statement, x);
}
/*
* Declare an empty synthesized constructor that looks like:
* function ClassName(){}
*
* Closure Compiler's RewriteFunctionExpressions pass can be enabled to turn these back
* into a factory method after optimizations.
*
* TODO(goktug): throw Error in the body to prevent instantiation via this constructor.
*/
private JsName declareSynthesizedClosureConstructor(JDeclaredType x) {
SourceInfo sourceInfo = x.getSourceInfo();
JsName classVar = topScope.declareName(JjsUtils.mangledNameString(x));
JsFunction closureCtor = JsUtils.createEmptyFunctionLiteral(sourceInfo, topScope, classVar);
JsExprStmt statement = closureCtor.makeStmt();
// This synthetic statement must be in the initial fragment, do not add to typeDefinitions
getGlobalStatements().add(statement);
names.put(x, classVar);
return classVar;
}
/*
* Sets up the castmap for type X
*/
private void setupCastMapForUnboxedType(JDeclaredType type, String castMapField) {
// Cast.[castMapName] = /* cast map */ { ..:1, ..:1}
JsName castableTypeMapName = getIndexedFieldJsName(castMapField);
JsNameRef castMapVarRef = castableTypeMapName.makeRef(type.getSourceInfo());
JsExpression castMapLiteral = generateCastableTypeMap(type);
addTypeDefinitionStatement(type, createAssignment(castMapVarRef, castMapLiteral).makeStmt());
}
private void maybeGenerateObjectMethodsAliases(JDeclaredType type) {
if (type == program.getTypeJavaLangObject()) {
// special: setup a "toString" alias for java.lang.Object.toString()
Set<JMethod> overridableJavaLangObjectMethods = ImmutableSet.of(
program.getIndexedMethodOrNull(RuntimeConstants.OBJECT_EQUALS),
program.getIndexedMethodOrNull(RuntimeConstants.OBJECT_HASHCODE),
program.getIndexedMethodOrNull(RuntimeConstants.OBJECT_TO_STRING));
for (JMethod method : type.getMethods()) {
if (overridableJavaLangObjectMethods.contains(method)) {
JsName methodJsName = objectScope.declareUnobfuscatableName(method.getName());
generatePrototypeDefinitionAlias(method, methodJsName);
}
}
}
}
private void generatePrototypeAssignment(JMethod method, JsName name, JsExpression rhs) {
generatePrototypeAssignment(method, name, rhs, method.getJsMemberType());
}
/**
* Create a vtable assignment of the form _.polyname = rhs; and register the line as
* created for {@code method}.
*/
private void generatePrototypeAssignment(JMethod method, JsName name, JsExpression rhs,
JsMemberType memberType) {
SourceInfo sourceInfo = method.getSourceInfo();
JsNameRef prototypeQualifierOf = getPrototypeQualifierOf(method);
JsNameRef lhs = name.makeQualifiedRef(sourceInfo, prototypeQualifierOf);
switch (memberType) {
case GETTER:
case SETTER:
emitPropertyImplementation(method, prototypeQualifierOf, name.makeRef(sourceInfo), rhs);
break;
default:
emitMethodImplementation(method, lhs, createAssignment(lhs, rhs).makeStmt());
break;
}
}
private void emitPropertyImplementation(JMethod method, JsNameRef prototype, JsNameRef name,
JsExpression methodDefinitionStatement) {
SourceInfo sourceInfo = method.getSourceInfo();
// We use Object.defineProperties instead of Object.defineProperty to make sure the
// property name appears as an identifier and not as a string.
// Some JS optimizers, e.g. the closure compiler, relies on this subtle difference for
// obfuscating property names.
JsNameRef definePropertyMethod =
getIndexedMethodJsName(RuntimeConstants.RUNTIME_DEFINE_PROPERTIES).makeRef(sourceInfo);
JsObjectLiteral definePropertyLiteral =
JsObjectLiteral.builder(sourceInfo)
// {name: {get: function() { ..... }} or {set : function (v) {....}}}
.add(name, JsObjectLiteral.builder(sourceInfo)
// {get: function() { ..... }} or {set : function (v) {....}}
.add(method.getJsMemberType().getPropertyAccessorKey(), methodDefinitionStatement)
.build())
.build();
addMethodDefinitionStatement(method, new JsInvocation(sourceInfo, definePropertyMethod,
prototype, definePropertyLiteral).makeStmt());
}
private void emitMethodImplementation(JMethod method, JsNameRef functionNameRef,
JsExprStmt methodDefinitionStatement) {
addMethodDefinitionStatement(method, methodDefinitionStatement);
if (shouldEmitDisplayNames()) {
JsExprStmt displayNameAssignment = outputDisplayName(functionNameRef, method);
addMethodDefinitionStatement(method, displayNameAssignment);
}
}
private void generatePrototypeDefinitionAlias(JMethod method, JsName alias) {
JsName polyName = polymorphicNames.get(method);
JsExpression bridge = JsUtils.createBridge(method, polyName, topScope);
// Aliases are never property accessors.
generatePrototypeAssignment(method, alias, bridge, JsMemberType.NONE);
}
private JsExprStmt outputDisplayName(JsNameRef function, JMethod method) {
JsNameRef displayName = new JsNameRef(function.getSourceInfo(), "displayName");
displayName.setQualifier(function);
String displayStringName = getDisplayName(method);
JsStringLiteral displayMethodName =
new JsStringLiteral(function.getSourceInfo(), displayStringName);
return createAssignment(displayName, displayMethodName).makeStmt();
}
private boolean shouldEmitDisplayNames() {
return methodNameMappingMode != OptionMethodNameDisplayMode.Mode.NONE;
}
private String getDisplayName(JMethod method) {
switch (methodNameMappingMode) {
case ONLY_METHOD_NAME:
return method.getName();
case ABBREVIATED:
return method.getEnclosingType().getShortName() + "." + method.getName();
case FULL:
return method.getEnclosingType().getName() + "." + method.getName();
default:
assert false : "Invalid display mode option " + methodNameMappingMode;
}
return null;
}
/**
* Creates the assignment for all polynames for a certain class, assumes that the global
* variable _ points the JavaScript prototype for {@code type}.
*/
private void generatePrototypeDefinitions(JDeclaredType type) {
assert !program.isRepresentedAsNativeJsPrimitive(type);
// Emit synthetic methods first. In JsInterop we allow a more user written method to be named
// with the same name as a synthetic bridge (required due to generics) relying that the
// synthetic method is output first into the prototype slot and rewritten in this situation.
// TODO(rluble): this is a band aid. The user written method (and its overrides) should be
// automatically JsIgnored. Otherwise some semantics become looser. E.g. the synthetic bridge
// method may be casting some of the parameters. Such casts are lost in this scheme.
Iterable<JMethod> orderedInstanceMethods = Iterables.concat(
Iterables.filter(type.getMethods(),
Predicates.and(
JjsPredicates.IS_SYNTHETIC,
JjsPredicates.NEEDS_DYNAMIC_DISPATCH)),
Iterables.filter(type.getMethods(),
Predicates.and(
Predicates.not(JjsPredicates.IS_SYNTHETIC),
JjsPredicates.NEEDS_DYNAMIC_DISPATCH)));
for (JMethod method : orderedInstanceMethods) {
generatePrototypeDefinition(method, (JsExpression) transformMethod(method));
}
}
private void generatePrototypeDefinition(JMethod method, JsExpression functionDefinition) {
if (functionDefinition != null) {
generatePrototypeAssignment(method, polymorphicNames.get(method), functionDefinition);
}
if (method.exposesNonJsMember()) {
JsName internalMangledName = interfaceScope.declareName(mangleNameForPoly(method),
method.getName());
generatePrototypeDefinitionAlias(method, internalMangledName);
}
if (method.exposesPackagePrivateMethod()) {
// Here is the situation where this is needed:
//
// class a.A { m() {} }
// class b.B extends a.A { m() {} }
// interface I { m(); }
// class a.C {
// { A a = new b.B(); a.m() // calls A::m()} }
// { I i = new b.B(); a.m() // calls B::m()} }
// }
//
// Up to this point it is clear that package private names need to be different than
// public names.
//
// Add class a.D extends a.A implements I { public m() }
//
// a.D collapses A::m and I::m into the same function and it was clear that two
// two different names were already needed, hence when creating the vtable for a.D
// both names have to point to the same function.
generatePrototypeDefinitionAlias(method, getPackagePrivateName(method));
}
}
/**
* Returns either _ or ClassCtor.prototype depending on output mode.
*/
private JsNameRef getPrototypeQualifierOf(JMember member) {
return getPrototypeQualifierOf(member.getEnclosingType(), member.getSourceInfo());
}
/**
* Returns either _ or ClassCtor.prototype depending on output mode.
*/
private JsNameRef getPrototypeQualifierOf(JDeclaredType type, SourceInfo info) {
return closureCompilerFormatEnabled
? prototype.makeQualifiedRef(info, names.get(type).makeRef(info))
: globalTemp.makeRef(info);
}
/**
* Returns the package private JsName for {@code method}.
*/
private JsName getPackagePrivateName(JMethod method) {
for (JMethod overridenMethod : method.getOverriddenMethods()) {
if (overridenMethod.isPackagePrivate()) {
JsName name = polymorphicNames.get(overridenMethod);
assert name != null;
return name;
}
}
throw new AssertionError(
method.toString() + " overrides a package private method but was not found.");
}
private void handleClinit(JDeclaredType type, JsFunction clinitFunction) {
clinitFunctionForType.put(type, clinitFunction);
JDeclaredType superClass = type.getSuperClass();
JsFunction superClinitFunction = superClass == null
? null : clinitFunctionForType.get(superClass.getClinitTarget());
clinitFunction.setSuperClinit(superClinitFunction);
List<JsStatement> statements = clinitFunction.getBody().getStatements();
SourceInfo sourceInfo = clinitFunction.getSourceInfo();
// Self-assign to the global noop method immediately (to prevent reentrancy). In incremental
// mode the more costly Object constructor function is used as the noop method since doing so
// provides a better debug experience that does not step into already used clinits.
JsName emptyFunctionFnName = incremental ? objectConstructorFunction.getName()
: getIndexedMethodJsName(RuntimeConstants.RUNTIME_EMPTY_METHOD);
JsExpression assignment = createAssignment(clinitFunction.getName().makeRef(sourceInfo),
emptyFunctionFnName.makeRef(sourceInfo));
statements.add(0, assignment.makeStmt());
}
private boolean isMethodPotentiallyCalledAcrossClasses(JMethod method) {
assert incremental || crossClassTargets != null;
return crossClassTargets == null || crossClassTargets.contains(method)
|| method.isJsInteropEntryPoint();
}
private Iterable<JMethod> getPotentiallyAliveConstructors(JDeclaredType x) {
return Iterables.filter(x.getMethods(), new Predicate<JMethod>() {
@Override
public boolean apply(JMethod m) {
return isMethodPotentiallyALiveConstructor(m);
}
});
}
/**
* Whether a method is a constructor that is actually newed. Note that in absence of whole
* world knowledge evey constructor is potentially live.
*/
private boolean isMethodPotentiallyALiveConstructor(JMethod method) {
if (!(method instanceof JConstructor)) {
return false;
}
assert incremental || liveCtors != null;
return liveCtors == null || liveCtors.contains(method);
}
private JsInvocation maybeCreateClinitCall(JField x) {
if (!x.isStatic() || x.isCompileTimeConstant()) {
// Access to compile time constants do not trigger class initialization (JLS 12.4.1).
return null;
}
JDeclaredType targetType = x.getEnclosingType().getClinitTarget();
if (targetType == null
|| targetType == program.getTypeClassLiteralHolder()
// When currentMethod == null, the clinit is being hoisted to the global scope.
|| (currentMethod != null
&& !currentMethod.getEnclosingType().checkClinitTo(targetType))) {
return null;
}
JMethod clinitMethod = targetType.getClinitMethod();
SourceInfo sourceInfo = x.getSourceInfo();
return new JsInvocation(sourceInfo, names.get(clinitMethod).makeRef(sourceInfo));
}
private JsInvocation maybeCreateClinitCall(JMethod method) {
if (!isMethodPotentiallyCalledAcrossClasses(method)) {
// Global optimized compile can prune some clinit calls.
return null;
}
JDeclaredType enclosingType = method.getEnclosingType();
if (method.canBePolymorphic() || (program.isStaticImpl(method) &&
!method.isJsOverlay())) {
return null;
}
if (enclosingType == null || !enclosingType.hasClinit()) {
return null;
}
// Avoid recursion sickness.
if (JProgram.isClinit(method)) {
return null;
}
JMethod clinitMethod = enclosingType.getClinitTarget().getClinitMethod();
SourceInfo sourceInfo = method.getSourceInfo();
return new JsInvocation(sourceInfo, names.get(clinitMethod).makeRef(sourceInfo));
}
/**
* If a field is a literal, we can potentially treat it as immutable and assign it once on the
* prototype, to be reused by all instances of the class, instead of re-assigning the same
* literal in each constructor.
*/
private boolean initializeAtTopScope(JField x) {
if (x.getEnclosingType().isJsFunctionImplementation()) {
// JsFunction implementation are plain JS functions with no class prototype, fields
// need to be initialized and placed on the instance itself.
return false;
}
if (x.getLiteralInitializer() == null) {
return false;
}
if (x.isFinal() || x.isStatic() || x.isCompileTimeConstant()) {
// we can definitely initialize at top-scope, as JVM does so as well
return true;
}
return !uninitializedValuePotentiallyObservable.apply(x);
}
/**
* Helpers to avoid casting (can be removed when compiling in Java 8).
*/
private <T extends JsExpression> T transform(JExpression expression) {
return transform((JNode) expression);
}
private <T extends JsStatement> T transform(JStatement statement) {
return transform((JNode) statement);
}
private JsBlock transform(JBlock statement) {
return transform((JNode) statement);
}
}
private void addVarsIfNotEmpty(JsVars vars) {
if (!vars.isEmpty()) {
getGlobalStatements().add(vars);
}
}
private List<JsStatement> getGlobalStatements() {
return jsProgram.getGlobalBlock().getStatements();
}
/**
* Return false if the method needs to be generated. Some methods do not need any output,
* in particular abstract methods and static intializers that are never called.
*/
private static boolean doesNotHaveConcreteImplementation(JMethod method) {
return method.isAbstract()
|| method.isJsNative()
|| JjsUtils.isJsMemberUnnecessaryAccidentalOverride(method)
|| (JProgram.isClinit(method)
&& method.getEnclosingType().getClinitTarget() != method.getEnclosingType());
}
private static class JavaToJsOperatorMap {
private static final Map<JBinaryOperator, JsBinaryOperator> bOpMap =
Maps.newEnumMap(JBinaryOperator.class);
private static final Map<JUnaryOperator, JsUnaryOperator> uOpMap =
Maps.newEnumMap(JUnaryOperator.class);
static {
bOpMap.put(JBinaryOperator.MUL, JsBinaryOperator.MUL);
bOpMap.put(JBinaryOperator.DIV, JsBinaryOperator.DIV);
bOpMap.put(JBinaryOperator.MOD, JsBinaryOperator.MOD);
bOpMap.put(JBinaryOperator.ADD, JsBinaryOperator.ADD);
bOpMap.put(JBinaryOperator.CONCAT, JsBinaryOperator.ADD);
bOpMap.put(JBinaryOperator.SUB, JsBinaryOperator.SUB);
bOpMap.put(JBinaryOperator.SHL, JsBinaryOperator.SHL);
bOpMap.put(JBinaryOperator.SHR, JsBinaryOperator.SHR);
bOpMap.put(JBinaryOperator.SHRU, JsBinaryOperator.SHRU);
bOpMap.put(JBinaryOperator.LT, JsBinaryOperator.LT);
bOpMap.put(JBinaryOperator.LTE, JsBinaryOperator.LTE);
bOpMap.put(JBinaryOperator.GT, JsBinaryOperator.GT);
bOpMap.put(JBinaryOperator.GTE, JsBinaryOperator.GTE);
bOpMap.put(JBinaryOperator.EQ, JsBinaryOperator.EQ);
bOpMap.put(JBinaryOperator.NEQ, JsBinaryOperator.NEQ);
bOpMap.put(JBinaryOperator.BIT_AND, JsBinaryOperator.BIT_AND);
bOpMap.put(JBinaryOperator.BIT_XOR, JsBinaryOperator.BIT_XOR);
bOpMap.put(JBinaryOperator.BIT_OR, JsBinaryOperator.BIT_OR);
bOpMap.put(JBinaryOperator.AND, JsBinaryOperator.AND);
bOpMap.put(JBinaryOperator.OR, JsBinaryOperator.OR);
bOpMap.put(JBinaryOperator.ASG, JsBinaryOperator.ASG);
bOpMap.put(JBinaryOperator.ASG_ADD, JsBinaryOperator.ASG_ADD);
bOpMap.put(JBinaryOperator.ASG_CONCAT, JsBinaryOperator.ASG_ADD);
bOpMap.put(JBinaryOperator.ASG_SUB, JsBinaryOperator.ASG_SUB);
bOpMap.put(JBinaryOperator.ASG_MUL, JsBinaryOperator.ASG_MUL);
bOpMap.put(JBinaryOperator.ASG_DIV, JsBinaryOperator.ASG_DIV);
bOpMap.put(JBinaryOperator.ASG_MOD, JsBinaryOperator.ASG_MOD);
bOpMap.put(JBinaryOperator.ASG_SHL, JsBinaryOperator.ASG_SHL);
bOpMap.put(JBinaryOperator.ASG_SHR, JsBinaryOperator.ASG_SHR);
bOpMap.put(JBinaryOperator.ASG_SHRU, JsBinaryOperator.ASG_SHRU);
bOpMap.put(JBinaryOperator.ASG_BIT_AND, JsBinaryOperator.ASG_BIT_AND);
bOpMap.put(JBinaryOperator.ASG_BIT_OR, JsBinaryOperator.ASG_BIT_OR);
bOpMap.put(JBinaryOperator.ASG_BIT_XOR, JsBinaryOperator.ASG_BIT_XOR);
uOpMap.put(JUnaryOperator.INC, JsUnaryOperator.INC);
uOpMap.put(JUnaryOperator.DEC, JsUnaryOperator.DEC);
uOpMap.put(JUnaryOperator.NEG, JsUnaryOperator.NEG);
uOpMap.put(JUnaryOperator.NOT, JsUnaryOperator.NOT);
uOpMap.put(JUnaryOperator.BIT_NOT, JsUnaryOperator.BIT_NOT);
}
public static JsBinaryOperator get(JBinaryOperator op) {
return bOpMap.get(op);
}
public static JsUnaryOperator get(JUnaryOperator op) {
return uOpMap.get(op);
}
}
private class CollectJsFunctionsForInlining extends JVisitor {
// JavaScript functions that arise from methods that were not inlined in the Java AST
// NOTE: We use a LinkedHashSet to preserve the order of insertion. So that the following passes
// that use this result are deterministic.
private Set<JsNode> functionsForJsInlining = Sets.newLinkedHashSet();
private JMethod currentMethod;
@Override
public void endVisit(JMethod x, Context ctx) {
if (x.isJsniMethod()) {
// These are methods whose bodies where not traversed by the Java method inliner.
JsFunction function = jsFunctionsByJavaMethodBody.get(x.getBody());
if (function != null && function.getBody() != null) {
functionsForJsInlining.add(function);
}
// Add all functions declared inside JSNI blocks as well.
assert function != null;
new JsModVisitor() {
@Override
public void endVisit(JsFunction x, JsContext ctx) {
functionsForJsInlining.add(x);
}
}.accept(function);
}
currentMethod = null;
}
@Override
public void endVisit(JMethodCall x, Context ctx) {
JMethod target = x.getTarget();
if (target.isInliningAllowed() && (target.isJsniMethod()
|| program.getIndexedTypes().contains(target.getEnclosingType())
|| target.getInliningMode() == InliningMode.FORCE_INLINE)) {
// These are either: 1) callsites to JSNI functions, in which case MethodInliner did not
// attempt to inline; 2) inserted by normalizations passes AFTER all inlining or 3)
// calls to methods annotated with @ForceInline that were not inlined by the simple
// MethodInliner.
JsFunction function = jsFunctionsByJavaMethodBody.get(currentMethod.getBody());
if (function != null && function.getBody() != null) {
functionsForJsInlining.add(function);
}
}
}
@Override
public boolean visit(JMethod x, Context ctx) {
currentMethod = x;
return true;
}
public Set<JsNode> getFunctionsForJsInlining() {
accept(program);
return functionsForJsInlining;
}
}
/**
* Computes:<p>
* <ul>
* <li> 1. whether a constructors are live directly (through being in a new operation) or
* indirectly (only called by other constructors). Only directly live constructors become
* JS constructor, otherwise they will behave like regular static functions.
* </li> 2. whether there exists cross class (static) calls or accesses that would need clinits to
* be triggered. If not clinits need only be called in constructors.
* <li>
* </li>
* </ul>
*/
private class RecordCrossClassCallsAndConstructorLiveness extends JVisitor {
// TODO(rluble): This analysis should be extracted from GenerateJavaScriptAST into its own
// JAVA optimization pass. Constructors that are not newed can be transformed into statified
// regular methods; and methods that are not called from outside the class boundary can be
// privatized. Currently we do not use the private modifier to avoid emitting clinits, instead
// we use the result of this analysis (private methods CAN be called from JSNI in an unrelated
// class, touche!).
{
crossClassTargets = Sets.newHashSet();
liveCtors = Sets.newIdentityHashSet();
}
private JMethod currentMethod;
@Override
public void endVisit(JMethod x, Context ctx) {
// methods which are exported or static indexed methods may be called externally
if (x.isJsInteropEntryPoint()
|| (x.isStatic() && program.getIndexedMethods().contains(x))) {
if (x instanceof JConstructor) {
// exported ctors always considered live
liveCtors.add((JConstructor) x);
}
// could be called from JS, so clinit must be called from body
crossClassTargets.add(x);
}
currentMethod = null;
}
@Override
public void endVisit(JMethodCall x, Context ctx) {
JDeclaredType sourceType = currentMethod.getEnclosingType();
JDeclaredType targetType = x.getTarget().getEnclosingType();
if (sourceType.checkClinitTo(targetType)) {
crossClassTargets.add(x.getTarget());
}
}
@Override
public void endVisit(JNewInstance x, Context ctx) {
super.endVisit(x, ctx);
liveCtors.add(x.getTarget());
}
@Override
public void endVisit(JProgram x, Context ctx) {
// Entry methods can be called externally, so they must run clinit.
crossClassTargets.addAll(x.getEntryMethods());
}
@Override
public void endVisit(JsniMethodRef x, Context ctx) {
if (x.getTarget() instanceof JConstructor) {
liveCtors.add((JConstructor) x.getTarget());
}
endVisit((JMethodCall) x, ctx);
}
@Override
public boolean visit(JMethod x, Context ctx) {
currentMethod = x;
return true;
}
}
private static class SortVisitor extends JVisitor {
@Override
public void endVisit(JClassType x, Context ctx) {
x.sortFields(HasName.BY_NAME_COMPARATOR);
x.sortMethods(JMethod.BY_SIGNATURE_COMPARATOR);
}
@Override
public void endVisit(JInterfaceType x, Context ctx) {
x.sortFields(HasName.BY_NAME_COMPARATOR);
x.sortMethods(JMethod.BY_SIGNATURE_COMPARATOR);
}
@Override
public void endVisit(JMethodBody x, Context ctx) {
x.sortLocals(HasName.BY_NAME_COMPARATOR);
}
@Override
public void endVisit(JProgram x, Context ctx) {
Collections.sort(x.getEntryMethods(), JMethod.BY_SIGNATURE_COMPARATOR);
Collections.sort(x.getDeclaredTypes(), HasName.BY_NAME_COMPARATOR);
}
@Override
public boolean visit(JMethodBody x, Context ctx) {
// No need to visit method bodies.
return false;
}
}
/**
* This is the main entry point for the translation from Java to JavaScript. Starts from a
* Java AST and constructs a JavaScript AST while collecting other useful information that
* is used in subsequent passes.
*
* @param logger a TreeLogger
* @param program a Java AST
* @param jsProgram an (empty) JavaScript AST
* @param symbolTable an (empty) symbol table that will be populated here
*
* @return A pair containing a JavaToJavaScriptMap and a Set of JsFunctions that need to be
* considered for inlining.
*/
public static Pair<JavaToJavaScriptMap, Set<JsNode>> exec(TreeLogger logger, JProgram program,
JsProgram jsProgram, CompilerContext compilerContext, TypeMapper<?> typeMapper,
Map<StandardSymbolData, JsName> symbolTable, PermutationProperties props) {
Event event = SpeedTracerLogger.start(CompilerEventType.GENERATE_JS_AST);
try {
GenerateJavaScriptAST generateJavaScriptAST = new GenerateJavaScriptAST(logger, program,
jsProgram, compilerContext, typeMapper, symbolTable, props);
return generateJavaScriptAST.execImpl();
} finally {
event.end();
}
}
private static final ImmutableList<String> METHODS_PROVIDED_BY_PREAMBLE = ImmutableList.of(
"Class.createForClass", "Class.createForPrimitive", "Class.createForInterface",
"Class.createForEnum");
private final Map<JBlock, JsCatch> catchMap = Maps.newIdentityHashMap();
private final Set<JsName> catchParamIdentifiers = Sets.newHashSet();
private final Map<JClassType, JsScope> classScopes = Maps.newIdentityHashMap();
/**
* A list of methods that are called from another class (ie might need to
* clinit).
*/
private Set<JMethod> crossClassTargets = null;
/**
* Contains JsNames for all interface methods. A special scope is needed so
* that independent classes will obfuscate their interface implementation
* methods the same way.
*/
private final JsScope interfaceScope;
private final JsProgram jsProgram;
private Set<JConstructor> liveCtors = null;
/**
* Classes that could potentially see uninitialized values for fields that are initialized in the
* declaration.
*/
private Predicate<JField> uninitializedValuePotentiallyObservable;
private final Map<JAbstractMethodBody, JsFunction> jsFunctionsByJavaMethodBody =
Maps.newIdentityHashMap();
private final Map<HasName, JsName> names = Maps.newIdentityHashMap();
/**
* Contains JsNames for the Object instance methods, such as equals, hashCode,
* and toString. All other class scopes have this scope as an ultimate parent.
*/
private final JsScope objectScope;
private final Map<JMethod, JsName> polymorphicNames = Maps.newIdentityHashMap();
private final JProgram program;
/**
* SEt of all targets of JNameOf.
*/
private Set<HasName> nameOfTargets = Sets.newHashSet();
private final TreeLogger logger;
/**
* Maps JsNames to machine-usable identifiers.
*/
private final Map<StandardSymbolData, JsName> symbolTable;
/**
* Contains JsNames for all globals, such as static fields and methods.
*/
private final JsScope topScope;
private final Map<JsStatement, JDeclaredType> javaTypeByGlobalStatement = Maps.newHashMap();
private final Map<JsStatement, JMethod> methodByGlobalStatement = Maps.newHashMap();
private final TypeMapper<?> typeMapper;
private final MinimalRebuildCache minimalRebuildCache;
private final PermutationProperties properties;
private JsFunction objectConstructorFunction;
private OptionMethodNameDisplayMode.Mode methodNameMappingMode;
private final boolean closureCompilerFormatEnabled;
private final boolean optimize;
// This is also used to do some final optimizations.
// TODO(rluble) move optimizations to a Java AST optimization pass.
private final boolean incremental;
/**
* If true, polymorphic functions are made anonymous vtable declarations and
* not assigned topScope identifiers.
*/
private final boolean stripStack;
private GenerateJavaScriptAST(TreeLogger logger, JProgram program, JsProgram jsProgram,
CompilerContext compilerContext, TypeMapper<?> typeMapper,
Map<StandardSymbolData, JsName> symbolTable, PermutationProperties properties) {
this.logger = logger;
this.program = program;
this.jsProgram = jsProgram;
this.topScope = jsProgram.getScope();
this.objectScope = jsProgram.getObjectScope();
this.interfaceScope = new JsNormalScope(objectScope, "Interfaces");
this.minimalRebuildCache = compilerContext.getMinimalRebuildCache();
this.symbolTable = symbolTable;
this.typeMapper = typeMapper;
this.properties = properties;
PrecompileTaskOptions options = compilerContext.getOptions();
this.optimize = options.getOptimizationLevel() > OptionOptimize.OPTIMIZE_LEVEL_DRAFT;
this.methodNameMappingMode = options.getMethodNameDisplayMode();
assert methodNameMappingMode != null;
this.incremental = options.isIncrementalCompileEnabled();
this.stripStack = JsStackEmulator.getStackMode(properties) == JsStackEmulator.StackMode.STRIP;
this.closureCompilerFormatEnabled = options.isClosureCompilerFormatEnabled();
this.objectConstructorFunction =
new JsFunction(SourceOrigin.UNKNOWN, topScope, topScope.findExistingName("Object"));
}
/**
* Retrieves the runtime typeId for {@code type}.
*/
JExpression getRuntimeTypeReference(JReferenceType type) {
return typeMapper.get(type);
}
private String mangleName(JField x) {
return JjsUtils.mangleMemberName(x.getEnclosingType().getName(), x.getName());
}
private String mangleNameForGlobal(JMethod method) {
String s =
JjsUtils.mangleMemberName(method.getEnclosingType().getName(), method.getName()) + "__";
for (JType type : method.getOriginalParamTypes()) {
s += type.getJavahSignatureName();
}
s += method.getOriginalReturnType().getJavahSignatureName();
return StringInterner.get().intern(s);
}
private String mangleNameForPackagePrivatePoly(JMethod method) {
assert method.isPackagePrivate() && !method.isStatic();
/*
* Package private instance methods in different package should not override each
* other, so they must have distinct polymorphic names. Therefore, add the
* package to the mangled name.
*/
String mangledName = Joiner.on("$").join(
"package_private",
JjsUtils.mangledNameString(method.getEnclosingType().getPackageName()),
JjsUtils.mangledNameString(method));
return StringInterner.get().intern(JjsUtils.constructManglingSignature(method, mangledName));
}
private String mangleNameForPoly(JMethod method) {
if (method.isPrivate()) {
return mangleNameForPrivatePoly(method);
} else if (method.isPackagePrivate()) {
return mangleNameForPackagePrivatePoly(method);
} else {
return mangleNameForPublicPoly(method);
}
}
private String mangleNameForPublicPoly(JMethod method) {
return StringInterner.get().intern(
JjsUtils.constructManglingSignature(method, JjsUtils.mangledNameString(method)));
}
private String mangleNameForPrivatePoly(JMethod method) {
assert method.isPrivate() && !method.isStatic();
/*
* Private instance methods in different classes should not override each
* other, so they must have distinct polymorphic names. Therefore, add the
* class name to the mangled name.
*/
String mangledName = Joiner.on("$").join(
"private",
JjsUtils.mangledNameString(method.getEnclosingType()),
JjsUtils.mangledNameString(method));
return StringInterner.get().intern(JjsUtils.constructManglingSignature(method, mangledName));
}
private final Map<JType, JDeclarationStatement> classLiteralDeclarationsByType =
Maps.newLinkedHashMap();
private void contructTypeToClassLiteralDeclarationMap() {
/*
* Must execute in clinit statement order, NOT field order, so that back
* refs to super classes are preserved.
*/
JMethodBody clinitBody =
(JMethodBody) program.getTypeClassLiteralHolder().getClinitMethod().getBody();
for (JStatement stmt : clinitBody.getStatements()) {
if (!(stmt instanceof JDeclarationStatement)) {
continue;
}
JDeclarationStatement classLiteralDeclaration = (JDeclarationStatement) stmt;
JType type = program.getTypeByClassLiteralField(
(JField) ((JDeclarationStatement) stmt).getVariableRef().getTarget());
assert !classLiteralDeclarationsByType.containsKey(type);
classLiteralDeclarationsByType.put(type, classLiteralDeclaration);
}
}
private Pair<JavaToJavaScriptMap, Set<JsNode>> execImpl() {
NameClashesFixer.exec(program);
uninitializedValuePotentiallyObservable = optimize
? ComputePotentiallyObservableUninitializedValues.analyze(program)
: Predicates.<JField>alwaysTrue();
new FindNameOfTargets().accept(program);
new SortVisitor().accept(program);
if (!incremental) {
// TODO(rluble): pull out this analysis and make it a Java AST optimization pass.
new RecordCrossClassCallsAndConstructorLiveness().accept(program);
}
// Map class literals to their respective types.
contructTypeToClassLiteralDeclarationMap();
new CreateNamesAndScopesVisitor().accept(program);
new GenerateJavaScriptTransformer().transform(program);
// TODO(spoon): Instead of gathering the information here, get it via
// SourceInfo
JavaToJavaScriptMap jjsMap = new JavaToJavaScriptMapImpl(program.getDeclaredTypes(),
names, javaTypeByGlobalStatement, methodByGlobalStatement);
Set<JsNode> functionsForJsInlining = incremental ? Collections.<JsNode>emptySet() :
new CollectJsFunctionsForInlining().getFunctionsForJsInlining();
return Pair.create(jjsMap, functionsForJsInlining);
}
private JsFunction getJsFunctionFor(JMethod jMethod) {
return jsFunctionsByJavaMethodBody.get(jMethod.getBody());
}
private JsName getIndexedMethodJsName(String indexedName) {
return names.get(program.getIndexedMethod(indexedName));
}
private JsName getIndexedFieldJsName(String indexedName) {
return names.get(program.getIndexedField(indexedName));
}
private static JsNameRef createGlobalQualifier(String qualifier, SourceInfo sourceInfo) {
return JsUtils.createQualifiedNameRef(JsInteropUtil.normalizeQualifier(qualifier), sourceInfo);
}
}