com.google.gwt.dev.jjs.impl.EnumOrdinalizer Maven / Gradle / Ivy
/*
* Copyright 2010 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 com.google.gwt.core.ext.TreeLogger;
import com.google.gwt.dev.jjs.SourceInfo;
import com.google.gwt.dev.jjs.ast.Context;
import com.google.gwt.dev.jjs.ast.JArrayType;
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.JDeclarationStatement;
import com.google.gwt.dev.jjs.ast.JEnumField;
import com.google.gwt.dev.jjs.ast.JEnumType;
import com.google.gwt.dev.jjs.ast.JExpression;
import com.google.gwt.dev.jjs.ast.JField;
import com.google.gwt.dev.jjs.ast.JFieldRef;
import com.google.gwt.dev.jjs.ast.JInstanceOf;
import com.google.gwt.dev.jjs.ast.JMethod;
import com.google.gwt.dev.jjs.ast.JMethodCall;
import com.google.gwt.dev.jjs.ast.JNewArray;
import com.google.gwt.dev.jjs.ast.JNode;
import com.google.gwt.dev.jjs.ast.JParameter;
import com.google.gwt.dev.jjs.ast.JPrimitiveType;
import com.google.gwt.dev.jjs.ast.JProgram;
import com.google.gwt.dev.jjs.ast.JType;
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.JsniMethodRef;
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.collect.Lists;
import com.google.gwt.thirdparty.guava.common.collect.Multimap;
import com.google.gwt.thirdparty.guava.common.collect.Ordering;
import com.google.gwt.thirdparty.guava.common.collect.Sets;
import com.google.gwt.thirdparty.guava.common.collect.TreeMultimap;
import java.util.Comparator;
import java.util.List;
import java.util.Set;
import java.util.TreeSet;
/**
* This optimizer replaces enum constants with their ordinal value (a simple
* int) when possible. We call this process "ordinalization".
*
* Generally, this can be done for enums that are only ever referred to by
* reference, or by their ordinal value. For the specific set of conditions
* under which ordinalization can proceed, see the notes for the nested class
* {@link EnumOrdinalizer.CannotBeOrdinalAnalyzer} below.
*
* This optimizer modifies enum classes to change their field constants to ints,
* and to remove initialization of those constants in the clinit method. An
* ordinalized enum class will not be removed from the AST by this optimizer,
* but as long as all references to it are replaced, then the enum class itself
* will be pruned by subsequent optimizer passes. Some enum classes may not be
* completely removed however. Ordinalization can proceed in cases where there
* are added static fields or methods in the enum class. In such cases a reduced
* version of the original enum class can remain in the AST, containing only
* static fields and methods which aren't part of the enum infrastructure (in
* which case it will no longer behave as an enum class at all).
*
* Regardless of whether an ordinalized enum class ends up being completely
* pruned away, the AST is expected to be in a coherent and usable state after
* any pass of this optimizer. Thus, this optimizer should be considered to be
* stateless.
*
* The process is broken up into 2 separate passes over the AST, each
* implemented as a separate visitor class. The first visitor,
* {@link EnumOrdinalizer.CannotBeOrdinalAnalyzer} compiles information about
* each enum class in the AST, and looks for reasons not to ordinalize each
* enum. Thus, it prepares a "black-list" of enum classes that cannot be
* ordinalized (and it follows that all enums that don't get entered in the
* black-list, will be allowed to be ordinalized. The set of conditions which
* cause an enum to be black-listed are outlined below.
*
* If there are enum classes that didn't get black-listed remaining, the
* subsequent passes of the optimizer will be invoked. The first,
* {@link ReplaceOrdinalizedEnumTypes}, replaces the type info
* for each field or expression involved with a target enum constant with an
* integer. Also replaces access to the field {@code ordinal} and to the method
* {@code ordinal} with the appropriate ordinal value.
*/
public class EnumOrdinalizer {
/**
* A simple Tracker class for compiling lists of enum classes processed by
* this optimizer. If enabled, the results can be logged as debug output, and
* the results can be tested after running with a given input.
*/
public static class Tracker {
private static final Comparator SOURCE_INFO_COMPARATOR =
new Comparator() {
@Override
public int compare(SourceInfo s1, SourceInfo s2) {
int fileNameComp = s1.getFileName().compareTo(s2.getFileName());
return fileNameComp != 0 ? fileNameComp : s1.getStartLine()
- s2.getStartLine();
}
};
private final Set allEnumsOrdinalized = Sets.newTreeSet();
private final Set allEnumsVisited = Sets.newTreeSet();
private final Multimap enumInfoMap =
TreeMultimap.create(Ordering.natural(), SOURCE_INFO_COMPARATOR);
private final List> enumsOrdinalizedPerPass = Lists.newArrayList();
private final List> enumsVisitedPerPass = Lists.newArrayList();
private int runCount = -1;
// use TreeSets, for nice sorted iteration for output
public Tracker() {
// add entry for initial pass
enumsVisitedPerPass.add(new TreeSet());
enumsOrdinalizedPerPass.add(new TreeSet());
}
public void addEnumNotOrdinalizedInfo(String enumName, SourceInfo info) {
enumInfoMap.put(enumName, info);
}
public void addOrdinalized(String ordinalized) {
enumsOrdinalizedPerPass.get(runCount).add(ordinalized);
allEnumsOrdinalized.add(ordinalized);
}
public void addVisited(String visited) {
enumsVisitedPerPass.get(runCount).add(visited);
allEnumsVisited.add(visited);
}
public String getInfoString(SourceInfo info) {
if (info == null) {
return null;
}
return info.getFileName() + ": Line " + info.getStartLine();
}
public Set getOrdinalizedNames() {
return allEnumsOrdinalized;
}
public int getNumOrdinalized() {
return allEnumsOrdinalized.size();
}
public int getNumVisited() {
return allEnumsVisited.size();
}
public void incrementRunCount() {
runCount++;
enumsVisitedPerPass.add(new TreeSet());
enumsOrdinalizedPerPass.add(new TreeSet());
}
public boolean isOrdinalized(String className) {
return allEnumsOrdinalized.contains(className);
}
public boolean isVisited(String className) {
return allEnumsVisited.contains(className);
}
public void logEnumsNotOrdinalized(TreeLogger logger, TreeLogger.Type logType) {
if (logger == null) {
return;
}
boolean initialMessageLogged = false;
for (String enumVisited : allEnumsVisited) {
if (isOrdinalized(enumVisited)) {
continue;
}
if (!initialMessageLogged) {
logger = logger.branch(logType, "Enums Not Ordinalized:");
initialMessageLogged = true;
}
TreeLogger subLogger = logger.branch(logType, enumVisited);
for (SourceInfo info : enumInfoMap.get(enumVisited)) {
subLogger.branch(logType, getInfoString(info));
}
}
}
public void logEnumsOrdinalizedPerPass(TreeLogger logger, TreeLogger.Type logType) {
if (logger == null) {
return;
}
if (allEnumsOrdinalized.size() == 0) {
return;
}
int pass = 0;
for (Set enumsOrdinalized : enumsOrdinalizedPerPass) {
pass++;
if (enumsOrdinalized.size() > 0) {
TreeLogger subLogger = logger.branch(logType, "Pass " + pass + ": " +
enumsOrdinalized.size() + " ordinalized");
for (String enumOrdinalized : enumsOrdinalized) {
subLogger.branch(logType, enumOrdinalized);
}
}
}
}
public void logResultsDetailed(TreeLogger logger, TreeLogger.Type logType) {
logger = logResultsSummary(logger, logType);
logEnumsOrdinalizedPerPass(logger, logType);
logEnumsNotOrdinalized(logger, logType);
}
public TreeLogger logResultsSummary(TreeLogger logger, TreeLogger.Type logType) {
if (logger == null) {
return null;
}
logger = logger.branch(logType, "EnumOrdinalizer Results:");
logger.branch(logType, (runCount + 1) + " ordinalization passes completed");
logger.branch(logType, allEnumsOrdinalized.size() + " of " + allEnumsVisited.size()
+ " ordinalized");
return logger;
}
public void maybeDumpAST(JProgram program, int stage) {
AstDumper.maybeDumpAST(program, NAME + "_" + (runCount + 1) + "_" + stage);
}
}
/**
* A visitor which keeps track of the enums which cannot be ordinalized. It
* does this by keeping track of a "black-list" for ordinals which violate the
* conditions for ordinalization, below.
*
* An enum cannot be ordinalized, if it:
*
* - is implicitly upcast.
* - is implicitly cast to from a nullType.
* - is implicitly cast to or from a javaScriptObject type.
* - is explicitly cast to another type (or vice-versa).
* - is tested in an instanceof expression.
* - it's class literal is used explicitly.
* - has any field referenced, except for:
*
* - static fields.
* - Enum.ordinal.
*
* - has any method called, except for:
*
* - ordinal().
* - Enum.ordinal().
* - Enum() super constructor.
* - Enum.createValueOfMap().
* - static methods other than valueOf().
*
*
*
* This visitor extends the ImplicitUpcastAnalyzer, which encapsulates all the
* conditions where implicit upcasting can occur in an AST. The rest of the
* logic for checking ordinalizability is encapsulated in this sub-class.
*
* It also keeps track of all enums encountered, so we can know if we need to
* continue with the other visitors of the optimizer after this visitor runs.
*
* We make special allowances not to check any code statements that appear
* within the ClassLiteralHolder class, which can contain a reference to all
* enum class literals in the program, even after ordinalization occurs.
*
* Also, we ignore visiting the getClass() method for any enum subclass, since
* it will also cause a visit to the enum's class literal, and we don't
* necessarily want to prevent ordinalization in that case.
*
* Special checking is needed to detect a class literal reference that occurs
* within a JSNI method body. We don't get a visit to JClassLiteral in that
* case, so we need to inspect visits to JsniFieldRef for the possibility it
* might be a reference to a class literal.
*
* We also skip any checking in a method call to Enum.createValueOfMap(),
* since this is generated for any enum class initially within the extra
* enumClass$Map class, and this call contains an implicit upcast in the
* method call args (as well as a reference to the static enumClass$VALUES
* field), which we want to ignore. The enumClass$Map class will not get
* pruned as long as the enumClass is not ordinalized, and so we need to
* ignore it's presence in the consideration for whether an enum class is
* ordinalizable.
*/
private class CannotBeOrdinalAnalyzer extends ImplicitUpcastAnalyzer {
public CannotBeOrdinalAnalyzer(JProgram program) {
super(program);
}
@Override
public void endVisit(JCastOperation x, Context ctx) {
// check for explicit cast (check both directions)
blackListIfEnumCast(x.getExpr().getType(), x.getCastType(), x.getSourceInfo());
blackListIfEnumCast(x.getCastType(), x.getExpr().getType(), x.getSourceInfo());
}
@Override
public void endVisit(JClassLiteral x, Context ctx) {
/*
* Check for references to an enum's class literal. We need to black-list
* classes in this case, since there could be a call to
* Enum.valueOf(someEnum.class,"name"), etc.
*
* Note: we won't get here for class literals that occur in the
* ClassLiteralHolder class, or within the getClass method of an enum
* class (see comments above).
*/
blackListIfEnum(x.getRefType(), x.getSourceInfo());
}
@Override
public void endVisit(JClassType x, Context ctx) {
// keep track of all enum classes visited
JEnumType maybeEnum = x.isEnumOrSubclass();
if (maybeEnum == null) {
return;
}
enumsVisited.add(maybeEnum);
// don't need to re-ordinalize a previously ordinalized enum
if (maybeEnum.isOrdinalized()) {
addToBlackList(maybeEnum, x.getSourceInfo());
}
}
@Override
public void endVisit(JFieldRef x, Context ctx) {
// don't need to check Enum.ordinal
if (x.getField() == enumOrdinalField) {
return;
}
if (x.getInstance() != null) {
// check any instance field reference other than ordinal
blackListIfEnumExpression(x.getInstance());
}
}
@Override
public void endVisit(JInstanceOf x, Context ctx) {
// If any instanceof tests haven't been optimized out, black list.
blackListIfEnum(x.getExpr().getType(), x.getSourceInfo());
// TODO (jbrosenberg): Investigate further whether ordinalization can be
// allowed in this case.
blackListIfEnum(x.getTestType(), x.getSourceInfo());
}
@Override
public void endVisit(JMethodCall x, Context ctx) {
// exempt calls to certain methods on the Enum super class
if (x.getTarget() == enumCreateValueOfMapMethod || x.getTarget() == enumSuperConstructor
|| x.getTarget() == enumOrdinalMethod) {
return;
}
// any other method on an enum class should cause it to be black-listed
if (x.getInstance() != null) {
blackListIfEnumExpression(x.getInstance());
} else if (x.getTarget().isStatic()) {
// black-list static method calls on an enum class only for valueOf()
// and values()
JMethod target = x.getTarget();
maybeBlackListDueToStaticCall(x.getSourceInfo(), target);
}
if (x.getTarget().isNative()) {
// Black list enum types declared in parameters of native functions.
for (JParameter parameter :x.getTarget().getParams()) {
blackListIfEnum(parameter.getType(), x.getSourceInfo());
}
}
// defer to ImplicitUpcastAnalyzer to check method call args & params
super.endVisit(x, ctx);
}
@Override
public void endVisit(JsniClassLiteral x, Context ctx) {
/*
* Check for references to an enum's class literal. We need to black-list
* classes in this case, since there could be a call to
* Enum.valueOf(someEnum.class,"name"), etc.
*
* Note: we won't get here for class literals that occur in the
* ClassLiteralHolder class, or within the getClass method of an enum
* class (see comments above).
*/
blackListIfEnum(x.getRefType(), x.getSourceInfo());
}
@Override
public void endVisit(JsniFieldRef x, Context ctx) {
/*
* Can't do the same thing as for JFieldRef, all JsniFieldRefs are cast to
* JavaScriptObjects. Need to check both the field type and the type of
* the instance or enclosing class referencing the field.
*/
// check the field type
blackListIfEnum(x.getField().getType(), x.getSourceInfo());
// check the referrer
if (x.getInstance() != null) {
blackListIfEnumExpression(x.getInstance());
} else {
blackListIfEnum(x.getField().getEnclosingType(), x.getSourceInfo());
}
}
@Override
public void endVisit(JsniMethodRef x, Context ctx) {
// no enum methods are exempted if occur within a JsniMethodRef
if (x.getInstance() != null) {
blackListIfEnumExpression(x.getInstance());
} else if (x.getTarget().isStatic()) {
maybeBlackListDueToStaticCall(x.getSourceInfo(), x.getTarget());
}
// Black list enums returned to JSNI.
blackListIfEnum(x.getTarget().getType(), x.getSourceInfo());
// defer to ImplicitUpcastAnalyzer to check method call args & params
super.endVisit(x, ctx);
}
@Override
public boolean visit(JNewArray x, Context ctx) {
// Do not visit the implicit Class literal.
if (x.dims != null) {
accept(x.dims);
}
if (x.initializers != null) {
accept(x.initializers);
}
return false;
}
@Override
public boolean visit(JClassType x, Context ctx) {
/*
* Don't want to visit the large ClassLiteralHolder class, it doesn't
* contain references to actual usage of enum class literals. It's also a
* time savings to not traverse this class.
*/
if (x == classLiteralHolderType) {
return false;
}
return true;
}
@Override
public boolean visit(JMethod x, Context ctx) {
/*
* Don't want to visit the generated getClass() method on an enum, since
* it contains a reference to an enum's class literal that we don't want
* to consider. Make sure this is not a user overloaded version (i.e.
* check that it has no params).
*/
if (x.getEnclosingType().isEnumOrSubclass() != null && x.getName().equals("getClass")
&& (x.getOriginalParamTypes() == null || x.getOriginalParamTypes().size() == 0)) {
return false;
}
// defer to parent method on ImplicitCastAnalyzer
return super.visit(x, ctx);
}
@Override
public boolean visit(JMethodCall x, Context ctx) {
/*
* Skip all calls to Enum.createValueOfMap, since they'd get falsely
* flagged for implicitly upcasting an array of an enum class, in the
* arg passing. This method is only used by the enumClass$Map class to
* support Enum.valueOf(Class,String), which if reachable already prevents
* the enum from being ordinalized. Once ordinalization proceeds,
* this $Map class should be pruned.
*/
if (x.getTarget() == enumCreateValueOfMapMethod) {
return false;
}
// ok to visit
return true;
}
/*
* Override for the method called from ImplicitUpcastAnalyzer, which will be
* called for any implicit upcast.
*/
@Override
protected void processImplicitUpcast(JType fromType, JType destType, SourceInfo info) {
if (fromType.isNullType()) {
// handle case where a nullType is cast to an enum
blackListIfEnum(destType, info);
} else if (fromType == javaScriptObjectType) {
// handle case where a javaScriptObject is cast to an enum
blackListIfEnum(destType, info);
} else {
blackListIfEnumCast(fromType, destType, info);
}
}
private void addToBlackList(JEnumType enumType, SourceInfo info) {
ordinalizationBlackList.add(enumType);
if (tracker != null) {
tracker.addEnumNotOrdinalizedInfo(enumType.getName(), info);
}
}
private void blackListIfEnum(JType maybeEnum, SourceInfo info) {
JEnumType actualEnum = maybeEnum.isEnumOrSubclass();
if (actualEnum != null) {
addToBlackList(actualEnum, info);
}
}
private void blackListIfEnumCast(JType maybeEnum, JType destType, SourceInfo info) {
JEnumType actualEnum = maybeEnum.isEnumOrSubclass();
JEnumType actualDestType = destType.isEnumOrSubclass();
if (actualEnum != null) {
if (actualDestType != actualEnum) {
addToBlackList(actualEnum, info);
}
return;
}
// check JArrayTypes of enums
actualEnum = getEnumTypeFromArrayLeafType(maybeEnum);
actualDestType = getEnumTypeFromArrayLeafType(destType);
if (actualEnum != null) {
if (actualDestType != actualEnum) {
addToBlackList(actualEnum, info);
}
}
}
private void blackListIfEnumExpression(JExpression instance) {
if (instance != null) {
blackListIfEnum(instance.getType(), instance.getSourceInfo());
}
}
/**
* Blacklist the enum if there is a call to MyEnum.valueOf().
*/
private void maybeBlackListDueToStaticCall(SourceInfo info, JMethod target) {
if (target.getEnclosingType().isEnumOrSubclass() != null &&
(target.getName().equals("valueOf"))) {
blackListIfEnum(target.getEnclosingType(), info);
}
}
}
/**
* A visitor which replaces enum types with an integer.
*
* It sub-classes TypeRemapper, which encapsulates all the locations for a
* settable type. The overridden remap() method will be called in each
* instance, and it will test whether the type is a candidate for replacement,
* and if so, return the new type to set (JPrimitiveType.INT).
*
* Any reference to an enum field constant in an expression is replaced with
* integer.
*
* This will also explicitly replace an enum's field constants with its
* ordinal int values; also replaces access to the ordinal field and class to
* the ordinal() method with the corresponding int value.
*/
private class ReplaceOrdinalizedEnumTypes extends TypeRemapper {
public ReplaceOrdinalizedEnumTypes(OptimizerContext optimizerCtx) {
super(optimizerCtx);
}
@Override
public boolean visit(JClassType x, Context ctx) {
if (canBeOrdinal(x)) {
/*
* Remove any static impl mappings for any methods in an ordinal enum
* class. An ordinalized enum will no longer have an instance passed as
* the first argument for a static impl (it will just be an int). This
* is needed to preserve proper assumptions about static impls by other
* optimizers (e.g. we might need to insert a clinit, when it wouldn't
* be needed if a method call still had a static impl target).
*/
for (JMethod method : x.getMethods()) {
program.removeStaticImplMapping(method);
}
}
return true;
}
@Override
public void endVisit(JFieldRef x, Context ctx) {
super.endVisit(x, ctx);
JField field = x.getField();
if (field instanceof JEnumField && canBeOrdinal(field.getEnclosingType())
&& !ctx.isLvalue()) {
int ordinal = ((JEnumField) field).ordinal();
ctx.replaceMe(program.getLiteralInt(ordinal));
return;
}
maybeReplaceOrdinalAccess(x.getInstance(), field, ctx);
}
@Override
public void endVisit(JMethodCall x, Context ctx) {
super.endVisit(x, ctx);
maybeReplaceOrdinalAccess(x.getInstance(),x.getTarget(), ctx);
}
@Override
public void endVisit(JDeclarationStatement x, Context ctx) {
super.endVisit(x, ctx);
if (!(x.getVariableRef().getTarget() instanceof JEnumField)) {
return;
}
JEnumField enumField = (JEnumField) x.getVariableRef().getTarget();
if (!(canBeOrdinal(enumField.getEnclosingType()))) {
return;
}
// Also replace the declaration statement so that the enum instances are not constructed;
// eventually the field will be pruned but the declaration statement will only completely
// disappear if there are no side effects (constructing a new instance counts as side
// effects).
ctx.replaceMe(new JDeclarationStatement(x.getSourceInfo(), x.getVariableRef(),
program.getLiteralInt(enumField.ordinal())));
}
/**
* Remap enum types with JPrimitiveType.INT. Also handle case for arrays,
* replace enum leaftype with JPrimitive.INT. This is an override
* implementation called from TypeRemapper.
*/
@Override
protected JType remap(JType type) {
JType remappedType = getOrdinalizedType(type);
if (remappedType == null) {
return type;
}
return remappedType;
}
private boolean canBeOrdinal(JType type) {
JType uType = type.getUnderlyingType();
return uType instanceof JEnumType && !ordinalizationBlackList.contains(uType);
}
private JType getOrdinalizedType(JType type) {
if (canBeOrdinal(type)) {
return JPrimitiveType.INT;
}
JType uType = type.getUnderlyingType();
if (!(uType instanceof JArrayType)) {
return null;
}
JArrayType aType = (JArrayType) uType;
JType leafType = aType.getLeafType();
if (canBeOrdinal(leafType)) {
JArrayType newAType = program.getOrCreateArrayType(JPrimitiveType.INT, aType.getDims());
return !type.canBeNull() ? newAType.strengthenToNonNull() : newAType;
}
return null;
}
private void maybeReplaceOrdinalAccess(JExpression instance, JNode member, Context ctx) {
if (member != enumOrdinalField && member != enumOrdinalMethod) {
return;
}
JType instanceType = instance.getType();
// Access to x.ordinal and x.ordinal() need to be replaced by x if the type was ordinalized.
// Ordinalized types in this stage can also appear as primitive ints.
if (instanceType == JPrimitiveType.INT || canBeOrdinal(instanceType)) {
ctx.replaceMe(instance);
}
}
}
private static final String NAME = EnumOrdinalizer.class.getSimpleName();
private static Tracker tracker = null;
private static boolean trackerEnabled =
(System.getProperty("gwt.enableEnumOrdinalizerTracking") != null);
public static void enableTracker() {
trackerEnabled = true;
}
public static OptimizerStats exec(JProgram program, OptimizerContext optimizerCtx) {
Event optimizeEvent = SpeedTracerLogger.start(CompilerEventType.OPTIMIZE, "optimizer", NAME);
startTracker();
OptimizerStats stats = new EnumOrdinalizer(program).execImpl(optimizerCtx);
optimizerCtx.incOptimizationStep();
optimizeEvent.end("didChange", "" + stats.didChange());
return stats;
}
public static Tracker getTracker() {
return tracker;
}
public static void resetTracker() {
if (tracker != null) {
tracker = null;
startTracker();
}
}
private static void startTracker() {
if (trackerEnabled && tracker == null) {
tracker = new Tracker();
}
}
private final JType classLiteralHolderType;
private final JMethod enumCreateValueOfMapMethod;
private final JField enumOrdinalField;
private final JMethod enumOrdinalMethod;
private final JMethod enumSuperConstructor;
private final Set enumsVisited = Sets.newHashSet();
private final JType javaScriptObjectType;
private final Set ordinalizationBlackList = Sets.newHashSet();
private final JProgram program;
public EnumOrdinalizer(JProgram program) {
this.program = program;
this.classLiteralHolderType = program.getTypeClassLiteralHolder();
this.javaScriptObjectType = program.getJavaScriptObject();
this.enumOrdinalField = program.getIndexedField("Enum.ordinal");
this.enumCreateValueOfMapMethod = program.getIndexedMethod("Enum.createValueOfMap");
this.enumOrdinalMethod = program.getIndexedMethod("Enum.ordinal");
this.enumSuperConstructor = program.getIndexedMethod("Enum.Enum");
}
private OptimizerStats execImpl(OptimizerContext optimizerCtx) {
OptimizerStats stats = new OptimizerStats(NAME);
if (tracker != null) {
tracker.incrementRunCount();
tracker.maybeDumpAST(program, 0);
}
// Create black list of enum refs which can't be converted to an ordinal ref
CannotBeOrdinalAnalyzer ordinalAnalyzer = new CannotBeOrdinalAnalyzer(program);
ordinalAnalyzer.accept(program);
// Bail if we don't need to do any ordinalization
if (enumsVisited.size() == ordinalizationBlackList.size()) {
// Update tracker stats
if (tracker != null) {
for (JEnumType type : enumsVisited) {
tracker.addVisited(type.getName());
}
}
return stats;
}
// Replace enum type refs
ReplaceOrdinalizedEnumTypes replaceEnums = new ReplaceOrdinalizedEnumTypes(optimizerCtx);
replaceEnums.accept(program);
stats.recordModified(replaceEnums.getNumMods());
if (tracker != null) {
tracker.maybeDumpAST(program, 1);
}
// Update enums ordinalized, and tracker stats
for (JEnumType type : enumsVisited) {
if (tracker != null) {
tracker.addVisited(type.getName());
}
if (!ordinalizationBlackList.contains(type)) {
if (tracker != null) {
tracker.addOrdinalized(type.getName());
}
type.setOrdinalized();
}
}
JavaAstVerifier.assertProgramIsConsistent(program);
return stats;
}
private JEnumType getEnumTypeFromArrayLeafType(JType type) {
type = type.getUnderlyingType();
if (type instanceof JArrayType) {
type = ((JArrayType) type).getLeafType();
return type.isEnumOrSubclass();
}
return null;
}
}