src/main/java/com/android/tools/r8/ir/analysis/type/TypeLatticeElement.java - r8 - Git at Google

 // Copyright (c) 2017, the R8 project authors. Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.
 package com.android.tools.r8.ir.analysis.type;

 import com.android.tools.r8.errors.Unreachable;
 import com.android.tools.r8.graph.AppInfo;
 import com.android.tools.r8.graph.DexClass;
 import com.android.tools.r8.graph.DexItemFactory;
 import com.android.tools.r8.graph.DexType;
 import com.android.tools.r8.ir.code.NumericType;
 import com.android.tools.r8.ir.code.Value;
 import com.android.tools.r8.utils.LRUCacheTable;
 import com.google.common.collect.ImmutableSet;
 import java.util.ArrayDeque;
 import java.util.HashSet;
 import java.util.IdentityHashMap;
 import java.util.Map;
 import java.util.Queue;
 import java.util.Set;

 /**
  * The base abstraction of lattice elements for local type analysis.
  */
 public abstract class TypeLatticeElement {
   public static final BottomTypeLatticeElement BOTTOM = BottomTypeLatticeElement.getInstance();
   public static final TopTypeLatticeElement TOP = TopTypeLatticeElement.getInstance();
   public static final IntTypeLatticeElement INT = IntTypeLatticeElement.getInstance();
   public static final FloatTypeLatticeElement FLOAT = FloatTypeLatticeElement.getInstance();
   public static final SingleTypeLatticeElement SINGLE = SingleTypeLatticeElement.getInstance();
   public static final LongTypeLatticeElement LONG = LongTypeLatticeElement.getInstance();
   public static final DoubleTypeLatticeElement DOUBLE = DoubleTypeLatticeElement.getInstance();
   public static final WideTypeLatticeElement WIDE = WideTypeLatticeElement.getInstance();
   public static final ReferenceTypeLatticeElement NULL =
       ReferenceTypeLatticeElement.getNullTypeLatticeElement();

   private static final LRUCacheTable<Set<DexType>, Set<DexType>, Set<DexType>>
       leastUpperBoundOfInterfacesTable = LRUCacheTable.create(8, 8);

   // TODO(b/72693244): Switch to NullLatticeElement.
   private final boolean isNullable;

   TypeLatticeElement(boolean isNullable) {
     this.isNullable = isNullable;
   }

   public boolean isNullable() {
     return isNullable;
   }

   public NullLatticeElement nullElement() {
     if (isNull()) {
       return NullLatticeElement.definitelyNull();
     }
     if (!isNullable()) {
       return NullLatticeElement.definitelyNotNull();
     }
     return NullLatticeElement.maybeNull();
   }

   /**
    * Defines how to join with null or switch to nullable lattice element.
    *
    * @return {@link TypeLatticeElement} a result of joining with null.
    */
   public abstract TypeLatticeElement asNullable();

   /**
    * Defines how to switch to non-nullable lattice element.
    *
    * @return {@link TypeLatticeElement} a similar lattice element with nullable flag flipped.
    */
   public TypeLatticeElement asNonNullable() {
     return BOTTOM;
   }

   String isNullableString() {
     return isNullable() ? "" : "@NonNull ";
   }

   /**
    * Computes the least upper bound of the current and the other elements.
    *
    * @param other {@link TypeLatticeElement} to join.
    * @param appInfo {@link AppInfo}.
    * @return {@link TypeLatticeElement}, a least upper bound of {@param this} and {@param other}.
    */
   public TypeLatticeElement join(TypeLatticeElement other, AppInfo appInfo) {
     if (this == other) {
       return this;
     }
     if (isBottom()) {
       return other;
     }
     if (other.isBottom()) {
       return this;
     }
     if (isTop() || other.isTop()) {
       return TOP;
     }
     if (isNull()) {
       return other.asNullable();
     }
     if (other.isNull()) {
       return asNullable();
     }
     if (isPrimitive()) {
       return other.isPrimitive()
           ? PrimitiveTypeLatticeElement.join(
               asPrimitiveTypeLatticeElement(), other.asPrimitiveTypeLatticeElement())
           : TOP;
     }
     if (other.isPrimitive()) {
       // By the above case, !(isPrimitive())
       return TOP;
     }
     // From now on, this and other are precise reference types, i.e., either ArrayType or ClassType.
     assert isReference() && other.isReference();
     assert isPreciseType() && other.isPreciseType();
     boolean isNullable = isNullable() || other.isNullable();
     if (getClass() != other.getClass()) {
       return objectClassType(appInfo, isNullable);
     }
     // From now on, getClass() == other.getClass()
     if (isArrayType()) {
       assert other.isArrayType();
       ArrayTypeLatticeElement a1 = asArrayTypeLatticeElement();
       ArrayTypeLatticeElement a2 = other.asArrayTypeLatticeElement();
       // Identical types are the same elements
       if (a1.getArrayType() == a2.getArrayType()) {
         return a1.isNullable() ? a1 : a2;
       }
       // If non-equal, find the inner-most reference types for each.
       DexType a1BaseReferenceType = a1.getArrayBaseType(appInfo.dexItemFactory);
       int a1Nesting = a1.getNesting();
       if (a1BaseReferenceType.isPrimitiveType()) {
         a1Nesting--;
         a1BaseReferenceType = appInfo.dexItemFactory.objectType;
       }
       DexType a2BaseReferenceType = a2.getArrayBaseType(appInfo.dexItemFactory);
       int a2Nesting = a2.getNesting();
       if (a2BaseReferenceType.isPrimitiveType()) {
         a2Nesting--;
         a2BaseReferenceType = appInfo.dexItemFactory.objectType;
       }
       assert a1BaseReferenceType.isClassType() && a2BaseReferenceType.isClassType();
       // If any nestings hit zero object is the join.
       if (a1Nesting == 0 || a2Nesting == 0) {
         return objectClassType(appInfo, isNullable);
       }
       // If the nestings differ the join is the smallest nesting level.
       if (a1Nesting != a2Nesting) {
         int min = Math.min(a1Nesting, a2Nesting);
         return objectArrayType(appInfo, min, isNullable);
       }
       // For different class element types, compute the least upper bound of element types.
       DexType baseTypeLub =
           a1BaseReferenceType.computeLeastUpperBoundOfClasses(appInfo, a2BaseReferenceType);
       // Create the full array type.
       DexType arrayTypeLub = appInfo.dexItemFactory.createArrayType(a1Nesting, baseTypeLub);
       return fromDexType(arrayTypeLub, isNullable, appInfo);
     }
     if (isClassType()) {
       assert other.isClassType();
       ClassTypeLatticeElement c1 = asClassTypeLatticeElement();
       ClassTypeLatticeElement c2 = other.asClassTypeLatticeElement();
       DexType lubType =
           c1.getClassType().computeLeastUpperBoundOfClasses(appInfo, c2.getClassType());
       Set<DexType> c1lubItfs = c1.getInterfaces();
       Set<DexType> c2lubItfs = c2.getInterfaces();
       Set<DexType> lubItfs = null;
       if (c1lubItfs.size() == c2lubItfs.size() && c1lubItfs.containsAll(c2lubItfs)) {
         lubItfs = c1lubItfs;
       }
       if (lubItfs == null) {
         lubItfs = computeLeastUpperBoundOfInterfaces(appInfo, c1lubItfs, c2lubItfs);
       }
       return new ClassTypeLatticeElement(lubType, isNullable, lubItfs);
     }
     throw new Unreachable("unless a new type lattice is introduced.");
   }

   private enum InterfaceMarker {
     LEFT,
     RIGHT
   }

   private static class InterfaceWithMarker {
     final DexType itf;
     final InterfaceMarker marker;

     InterfaceWithMarker(DexType itf, InterfaceMarker marker) {
       this.itf = itf;
       this.marker = marker;
     }
   }

   public static Set<DexType> computeLeastUpperBoundOfInterfaces(
       AppInfo appInfo, Set<DexType> s1, Set<DexType> s2) {
     Set<DexType> cached = leastUpperBoundOfInterfacesTable.get(s1, s2);
     if (cached != null) {
       return cached;
     }
     cached = leastUpperBoundOfInterfacesTable.get(s2, s1);
     if (cached != null) {
       return cached;
     }
     Map<DexType, Set<InterfaceMarker>> seen = new IdentityHashMap<>();
     Queue<InterfaceWithMarker> worklist = new ArrayDeque<>();
     for (DexType itf1 : s1) {
       worklist.add(new InterfaceWithMarker(itf1, InterfaceMarker.LEFT));
     }
     for (DexType itf2 : s2) {
       worklist.add(new InterfaceWithMarker(itf2, InterfaceMarker.RIGHT));
     }
     while (!worklist.isEmpty()) {
       InterfaceWithMarker item = worklist.poll();
       DexType itf = item.itf;
       InterfaceMarker marker = item.marker;
       Set<InterfaceMarker> markers = seen.computeIfAbsent(itf, k -> new HashSet<>());
       // If this interface is a lower one in this set, skip.
       if (markers.contains(marker)) {
         continue;
       }
       // If this interface is already visited by the other set, add marker for this set and skip.
       if (markers.size() == 1) {
         markers.add(marker);
         continue;
       }
       // Otherwise, this type is freshly visited.
       markers.add(marker);
       // Put super interfaces into the worklist.
       DexClass itfClass = appInfo.definitionFor(itf);
       if (itfClass != null) {
         for (DexType superItf : itfClass.interfaces.values) {
           markers = seen.computeIfAbsent(superItf, k -> new HashSet<>());
           if (!markers.contains(marker)) {
             worklist.add(new InterfaceWithMarker(superItf, marker));
           }
         }
       }
     }

     ImmutableSet.Builder<DexType> commonBuilder = ImmutableSet.builder();
     for (Map.Entry<DexType, Set<InterfaceMarker>> entry : seen.entrySet()) {
       // Keep commonly visited interfaces only
       if (entry.getValue().size() < 2) {
         continue;
       }
       commonBuilder.add(entry.getKey());
     }
     Set<DexType> commonlyVisited = commonBuilder.build();

     ImmutableSet.Builder<DexType> lubBuilder = ImmutableSet.builder();
     for (DexType itf : commonlyVisited) {
       // If there is a strict sub interface of this interface, it is not the least element.
       boolean notTheLeast = false;
       for (DexType other : commonlyVisited) {
         if (other.isStrictSubtypeOf(itf, appInfo)) {
           notTheLeast = true;
           break;
         }
       }
       if (notTheLeast) {
         continue;
       }
       lubBuilder.add(itf);
     }
     Set<DexType> lub = lubBuilder.build();
     // Cache the computation result only if the given two sets of interfaces are different.
     if (s1.size() != s2.size() || !s1.containsAll(s2)) {
       synchronized (leastUpperBoundOfInterfacesTable) {
         leastUpperBoundOfInterfacesTable.put(s1, s2, lub);
       }
     }
     return lub;
   }

   public static TypeLatticeElement join(
       Iterable<TypeLatticeElement> typeLattices, AppInfo appInfo) {
     TypeLatticeElement result = BOTTOM;
     for (TypeLatticeElement other : typeLattices) {
       result = result.join(other, appInfo);
     }
     return result;
   }

   public static TypeLatticeElement joinTypes(
       Iterable<DexType> types, boolean isNullable, AppInfo appInfo) {
     TypeLatticeElement result = BOTTOM;
     for (DexType type : types) {
       result = result.join(fromDexType(type, isNullable, appInfo), appInfo);
     }
     return result;
   }

   /**
    * Determines the strict partial order of the given {@link TypeLatticeElement}s.
    *
    * @param other expected to be *strictly* bigger than {@param this}
    * @param appInfo {@link AppInfo} to compute the least upper bound of {@link TypeLatticeElement}
    * @return {@code true} if {@param this} is strictly less than {@param other}.
    */
   public boolean strictlyLessThan(TypeLatticeElement other, AppInfo appInfo) {
     if (equals(other)) {
       return false;
     }
     TypeLatticeElement lub = join(other, appInfo);
     return !equals(lub) && other.equals(lub);
   }

   /**
    * Determines the partial order of the given {@link TypeLatticeElement}s.
    *
    * @param other expected to be bigger than or equal to {@param this}
    * @param appInfo {@link AppInfo} to compute the least upper bound of {@link TypeLatticeElement}
    * @return {@code true} if {@param this} is less than or equal to {@param other}.
    */
   public boolean lessThanOrEqual(TypeLatticeElement other, AppInfo appInfo) {
     return equals(other) || strictlyLessThan(other, appInfo);
   }

   /**
    * Determines if this type is based on a missing class, directly or indirectly.
    *
    * @return {@code} true if this type is based on a missing class.
    */
   public boolean isBasedOnMissingClass(AppInfo appInfo) {
     return false;
   }

   /**
    * Represents a type that can be everything.
    *
    * @return {@code true} if the corresponding {@link Value} could be any kinds.
    */
   public boolean isTop() {
     return false;
   }

   /**
    * Represents an empty type.
    *
    * @return {@code true} if the type of corresponding {@link Value} is not determined yet.
    */
   public boolean isBottom() {
     return false;
   }

   public boolean isReference() {
     return false;
   }

   public boolean isArrayType() {
     return false;
   }

   public ArrayTypeLatticeElement asArrayTypeLatticeElement() {
     return null;
   }

   public boolean isClassType() {
     return false;
   }

   public ClassTypeLatticeElement asClassTypeLatticeElement() {
     return null;
   }

   public boolean isPrimitive() {
     return false;
   }

   public PrimitiveTypeLatticeElement asPrimitiveTypeLatticeElement() {
     return null;
   }

   public boolean isSingle() {
     return false;
   }

   public boolean isWide() {
     return false;
   }

   public boolean isInt() {
     return false;
   }

   public boolean isFloat() {
     return false;
   }

   public boolean isLong() {
     return false;
   }

   public boolean isDouble() {
     return false;
   }

   public boolean isPreciseType() {
     return isArrayType()
         || isClassType()
         || isNull()
         || isInt()
         || isFloat()
         || isLong()
         || isDouble()
         || isBottom();
   }

   /**
    * Should use {@link #isConstantNull()} or {@link #isDefinitelyNull()} instead.
    */
   @Deprecated
   public boolean isNull() {
     return false;
   }

   /**
    * Determines if this type only includes null values that are defined by a const-number
    * instruction in the same enclosing method.
    *
    * These null values can be assigned to any type.
    */
   public boolean isConstantNull() {
     return isNull();
   }

   /**
    * Determines if this type only includes null values.
    *
    * These null values cannot be assigned to any type. For example, it is a type error to "throw v"
    * where the value `v` satisfies isDefinitelyNull(), because the static type of `v` may not be a
    * subtype of Throwable.
    */
   public boolean isDefinitelyNull() {
     return nullElement().isDefinitelyNull();
   }

   public int requiredRegisters() {
     assert !isBottom() && !isTop();
     return isWide() ? 2 : 1;
   }

   static TypeLatticeElement objectClassType(AppInfo appInfo, boolean isNullable) {
     return fromDexType(appInfo.dexItemFactory.objectType, isNullable, appInfo);
   }

   static TypeLatticeElement objectArrayType(AppInfo appInfo, int nesting, boolean isNullable) {
     return fromDexType(
         appInfo.dexItemFactory.createArrayType(nesting, appInfo.dexItemFactory.objectType),
         isNullable, appInfo);
   }

   public static TypeLatticeElement classClassType(AppInfo appInfo) {
     return fromDexType(appInfo.dexItemFactory.classType, false, appInfo);
   }

   public static TypeLatticeElement stringClassType(AppInfo appInfo) {
     return fromDexType(appInfo.dexItemFactory.stringType, false, appInfo);
   }

   public static TypeLatticeElement fromDexType(DexType type, boolean isNullable, AppInfo appInfo) {
     if (type == DexItemFactory.nullValueType) {
       return NULL;
     }
     if (type.isPrimitiveType()) {
       return PrimitiveTypeLatticeElement.fromDexType(type);
     }
     return appInfo.dexItemFactory.createReferenceTypeLatticeElement(type, isNullable, appInfo);
   }

   public static TypeLatticeElement fromNumericType(NumericType type) {
     switch (type) {
       case BYTE:
       case CHAR:
       case SHORT:
       case INT:
         return INT;
       case LONG:
         return LONG;
       case FLOAT:
         return FLOAT;
       case DOUBLE:
         return DOUBLE;
       default:
         throw new Unreachable("Unexpected numeric type: " + type);
     }
   }

   public boolean isValueTypeCompatible(TypeLatticeElement other) {
     return (isReference() && other.isReference())
         || (isSingle() && other.isSingle())
         || (isWide() && other.isWide());
   }

   public static TypeLatticeElement newArray(DexType arrayType, boolean isNullable) {
     return new ArrayTypeLatticeElement(arrayType, isNullable);
   }

   public TypeLatticeElement arrayGet(AppInfo appInfo) {
     return BOTTOM;
   }

   public TypeLatticeElement checkCast(AppInfo appInfo, DexType castType) {
     TypeLatticeElement castTypeLattice = fromDexType(castType, isNullable(), appInfo);
     if (lessThanOrEqual(castTypeLattice, appInfo)) {
       return this;
     }
     return castTypeLattice;
   }

   @Override
   public abstract String toString();

   @Override
   public abstract boolean equals(Object o);

   @Override
   public abstract int hashCode();
 }
	// Copyright (c) 2017, the R8 project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.
	package com.android.tools.r8.ir.analysis.type;

	import com.android.tools.r8.errors.Unreachable;
	import com.android.tools.r8.graph.AppInfo;
	import com.android.tools.r8.graph.DexClass;
	import com.android.tools.r8.graph.DexItemFactory;
	import com.android.tools.r8.graph.DexType;
	import com.android.tools.r8.ir.code.NumericType;
	import com.android.tools.r8.ir.code.Value;
	import com.android.tools.r8.utils.LRUCacheTable;
	import com.google.common.collect.ImmutableSet;
	import java.util.ArrayDeque;
	import java.util.HashSet;
	import java.util.IdentityHashMap;
	import java.util.Map;
	import java.util.Queue;
	import java.util.Set;

	/**
	* The base abstraction of lattice elements for local type analysis.
	*/
	public abstract class TypeLatticeElement {
	public static final BottomTypeLatticeElement BOTTOM = BottomTypeLatticeElement.getInstance();
	public static final TopTypeLatticeElement TOP = TopTypeLatticeElement.getInstance();
	public static final IntTypeLatticeElement INT = IntTypeLatticeElement.getInstance();
	public static final FloatTypeLatticeElement FLOAT = FloatTypeLatticeElement.getInstance();
	public static final SingleTypeLatticeElement SINGLE = SingleTypeLatticeElement.getInstance();
	public static final LongTypeLatticeElement LONG = LongTypeLatticeElement.getInstance();
	public static final DoubleTypeLatticeElement DOUBLE = DoubleTypeLatticeElement.getInstance();
	public static final WideTypeLatticeElement WIDE = WideTypeLatticeElement.getInstance();
	public static final ReferenceTypeLatticeElement NULL =
	ReferenceTypeLatticeElement.getNullTypeLatticeElement();

	private static final LRUCacheTable<Set<DexType>, Set<DexType>, Set<DexType>>
	leastUpperBoundOfInterfacesTable = LRUCacheTable.create(8, 8);

	// TODO(b/72693244): Switch to NullLatticeElement.
	private final boolean isNullable;

	TypeLatticeElement(boolean isNullable) {
	this.isNullable = isNullable;
	}

	public boolean isNullable() {
	return isNullable;
	}

	public NullLatticeElement nullElement() {
	if (isNull()) {
	return NullLatticeElement.definitelyNull();
	}
	if (!isNullable()) {
	return NullLatticeElement.definitelyNotNull();
	}
	return NullLatticeElement.maybeNull();
	}

	/**
	* Defines how to join with null or switch to nullable lattice element.
	*
	* @return {@link TypeLatticeElement} a result of joining with null.
	*/
	public abstract TypeLatticeElement asNullable();

	/**
	* Defines how to switch to non-nullable lattice element.
	*
	* @return {@link TypeLatticeElement} a similar lattice element with nullable flag flipped.
	*/
	public TypeLatticeElement asNonNullable() {
	return BOTTOM;
	}

	String isNullableString() {
	return isNullable() ? "" : "@NonNull ";
	}

	/**
	* Computes the least upper bound of the current and the other elements.
	*
	* @param other {@link TypeLatticeElement} to join.
	* @param appInfo {@link AppInfo}.
	* @return {@link TypeLatticeElement}, a least upper bound of {@param this} and {@param other}.
	*/
	public TypeLatticeElement join(TypeLatticeElement other, AppInfo appInfo) {
	if (this == other) {
	return this;
	}
	if (isBottom()) {
	return other;
	}
	if (other.isBottom()) {
	return this;
	}
	if (isTop() \|\| other.isTop()) {
	return TOP;
	}
	if (isNull()) {
	return other.asNullable();
	}
	if (other.isNull()) {
	return asNullable();
	}
	if (isPrimitive()) {
	return other.isPrimitive()
	? PrimitiveTypeLatticeElement.join(
	asPrimitiveTypeLatticeElement(), other.asPrimitiveTypeLatticeElement())
	: TOP;
	}
	if (other.isPrimitive()) {
	// By the above case, !(isPrimitive())
	return TOP;
	}
	// From now on, this and other are precise reference types, i.e., either ArrayType or ClassType.
	assert isReference() && other.isReference();
	assert isPreciseType() && other.isPreciseType();
	boolean isNullable = isNullable() \|\| other.isNullable();
	if (getClass() != other.getClass()) {
	return objectClassType(appInfo, isNullable);
	}
	// From now on, getClass() == other.getClass()
	if (isArrayType()) {
	assert other.isArrayType();
	ArrayTypeLatticeElement a1 = asArrayTypeLatticeElement();
	ArrayTypeLatticeElement a2 = other.asArrayTypeLatticeElement();
	// Identical types are the same elements
	if (a1.getArrayType() == a2.getArrayType()) {
	return a1.isNullable() ? a1 : a2;
	}
	// If non-equal, find the inner-most reference types for each.
	DexType a1BaseReferenceType = a1.getArrayBaseType(appInfo.dexItemFactory);
	int a1Nesting = a1.getNesting();
	if (a1BaseReferenceType.isPrimitiveType()) {
	a1Nesting--;
	a1BaseReferenceType = appInfo.dexItemFactory.objectType;
	}
	DexType a2BaseReferenceType = a2.getArrayBaseType(appInfo.dexItemFactory);
	int a2Nesting = a2.getNesting();
	if (a2BaseReferenceType.isPrimitiveType()) {
	a2Nesting--;
	a2BaseReferenceType = appInfo.dexItemFactory.objectType;
	}
	assert a1BaseReferenceType.isClassType() && a2BaseReferenceType.isClassType();
	// If any nestings hit zero object is the join.
	if (a1Nesting == 0 \|\| a2Nesting == 0) {
	return objectClassType(appInfo, isNullable);
	}
	// If the nestings differ the join is the smallest nesting level.
	if (a1Nesting != a2Nesting) {
	int min = Math.min(a1Nesting, a2Nesting);
	return objectArrayType(appInfo, min, isNullable);
	}
	// For different class element types, compute the least upper bound of element types.
	DexType baseTypeLub =
	a1BaseReferenceType.computeLeastUpperBoundOfClasses(appInfo, a2BaseReferenceType);
	// Create the full array type.
	DexType arrayTypeLub = appInfo.dexItemFactory.createArrayType(a1Nesting, baseTypeLub);
	return fromDexType(arrayTypeLub, isNullable, appInfo);
	}
	if (isClassType()) {
	assert other.isClassType();
	ClassTypeLatticeElement c1 = asClassTypeLatticeElement();
	ClassTypeLatticeElement c2 = other.asClassTypeLatticeElement();
	DexType lubType =
	c1.getClassType().computeLeastUpperBoundOfClasses(appInfo, c2.getClassType());
	Set<DexType> c1lubItfs = c1.getInterfaces();
	Set<DexType> c2lubItfs = c2.getInterfaces();
	Set<DexType> lubItfs = null;
	if (c1lubItfs.size() == c2lubItfs.size() && c1lubItfs.containsAll(c2lubItfs)) {
	lubItfs = c1lubItfs;
	}
	if (lubItfs == null) {
	lubItfs = computeLeastUpperBoundOfInterfaces(appInfo, c1lubItfs, c2lubItfs);
	}
	return new ClassTypeLatticeElement(lubType, isNullable, lubItfs);
	}
	throw new Unreachable("unless a new type lattice is introduced.");
	}

	private enum InterfaceMarker {
	LEFT,
	RIGHT
	}

	private static class InterfaceWithMarker {
	final DexType itf;
	final InterfaceMarker marker;

	InterfaceWithMarker(DexType itf, InterfaceMarker marker) {
	this.itf = itf;
	this.marker = marker;
	}
	}

	public static Set<DexType> computeLeastUpperBoundOfInterfaces(
	AppInfo appInfo, Set<DexType> s1, Set<DexType> s2) {
	Set<DexType> cached = leastUpperBoundOfInterfacesTable.get(s1, s2);
	if (cached != null) {
	return cached;
	}
	cached = leastUpperBoundOfInterfacesTable.get(s2, s1);
	if (cached != null) {
	return cached;
	}
	Map<DexType, Set<InterfaceMarker>> seen = new IdentityHashMap<>();
	Queue<InterfaceWithMarker> worklist = new ArrayDeque<>();
	for (DexType itf1 : s1) {
	worklist.add(new InterfaceWithMarker(itf1, InterfaceMarker.LEFT));
	}
	for (DexType itf2 : s2) {
	worklist.add(new InterfaceWithMarker(itf2, InterfaceMarker.RIGHT));
	}
	while (!worklist.isEmpty()) {
	InterfaceWithMarker item = worklist.poll();
	DexType itf = item.itf;
	InterfaceMarker marker = item.marker;
	Set<InterfaceMarker> markers = seen.computeIfAbsent(itf, k -> new HashSet<>());
	// If this interface is a lower one in this set, skip.
	if (markers.contains(marker)) {
	continue;
	}
	// If this interface is already visited by the other set, add marker for this set and skip.
	if (markers.size() == 1) {
	markers.add(marker);
	continue;
	}
	// Otherwise, this type is freshly visited.
	markers.add(marker);
	// Put super interfaces into the worklist.
	DexClass itfClass = appInfo.definitionFor(itf);
	if (itfClass != null) {
	for (DexType superItf : itfClass.interfaces.values) {
	markers = seen.computeIfAbsent(superItf, k -> new HashSet<>());
	if (!markers.contains(marker)) {
	worklist.add(new InterfaceWithMarker(superItf, marker));
	}
	}
	}
	}

	ImmutableSet.Builder<DexType> commonBuilder = ImmutableSet.builder();
	for (Map.Entry<DexType, Set<InterfaceMarker>> entry : seen.entrySet()) {
	// Keep commonly visited interfaces only
	if (entry.getValue().size() < 2) {
	continue;
	}
	commonBuilder.add(entry.getKey());
	}
	Set<DexType> commonlyVisited = commonBuilder.build();

	ImmutableSet.Builder<DexType> lubBuilder = ImmutableSet.builder();
	for (DexType itf : commonlyVisited) {
	// If there is a strict sub interface of this interface, it is not the least element.
	boolean notTheLeast = false;
	for (DexType other : commonlyVisited) {
	if (other.isStrictSubtypeOf(itf, appInfo)) {
	notTheLeast = true;
	break;
	}
	}
	if (notTheLeast) {
	continue;
	}
	lubBuilder.add(itf);
	}
	Set<DexType> lub = lubBuilder.build();
	// Cache the computation result only if the given two sets of interfaces are different.
	if (s1.size() != s2.size() \|\| !s1.containsAll(s2)) {
	synchronized (leastUpperBoundOfInterfacesTable) {
	leastUpperBoundOfInterfacesTable.put(s1, s2, lub);
	}
	}
	return lub;
	}

	public static TypeLatticeElement join(
	Iterable<TypeLatticeElement> typeLattices, AppInfo appInfo) {
	TypeLatticeElement result = BOTTOM;
	for (TypeLatticeElement other : typeLattices) {
	result = result.join(other, appInfo);
	}
	return result;
	}

	public static TypeLatticeElement joinTypes(
	Iterable<DexType> types, boolean isNullable, AppInfo appInfo) {
	TypeLatticeElement result = BOTTOM;
	for (DexType type : types) {
	result = result.join(fromDexType(type, isNullable, appInfo), appInfo);
	}
	return result;
	}

	/**
	* Determines the strict partial order of the given {@link TypeLatticeElement}s.
	*
	* @param other expected to be strictly bigger than {@param this}
	* @param appInfo {@link AppInfo} to compute the least upper bound of {@link TypeLatticeElement}
	* @return {@code true} if {@param this} is strictly less than {@param other}.
	*/
	public boolean strictlyLessThan(TypeLatticeElement other, AppInfo appInfo) {
	if (equals(other)) {
	return false;
	}
	TypeLatticeElement lub = join(other, appInfo);
	return !equals(lub) && other.equals(lub);
	}

	/**
	* Determines the partial order of the given {@link TypeLatticeElement}s.
	*
	* @param other expected to be bigger than or equal to {@param this}
	* @param appInfo {@link AppInfo} to compute the least upper bound of {@link TypeLatticeElement}
	* @return {@code true} if {@param this} is less than or equal to {@param other}.
	*/
	public boolean lessThanOrEqual(TypeLatticeElement other, AppInfo appInfo) {
	return equals(other) \|\| strictlyLessThan(other, appInfo);
	}

	/**
	* Determines if this type is based on a missing class, directly or indirectly.
	*
	* @return {@code} true if this type is based on a missing class.
	*/
	public boolean isBasedOnMissingClass(AppInfo appInfo) {
	return false;
	}

	/**
	* Represents a type that can be everything.
	*
	* @return {@code true} if the corresponding {@link Value} could be any kinds.
	*/
	public boolean isTop() {
	return false;
	}

	/**
	* Represents an empty type.
	*
	* @return {@code true} if the type of corresponding {@link Value} is not determined yet.
	*/
	public boolean isBottom() {
	return false;
	}

	public boolean isReference() {
	return false;
	}

	public boolean isArrayType() {
	return false;
	}

	public ArrayTypeLatticeElement asArrayTypeLatticeElement() {
	return null;
	}

	public boolean isClassType() {
	return false;
	}

	public ClassTypeLatticeElement asClassTypeLatticeElement() {
	return null;
	}

	public boolean isPrimitive() {
	return false;
	}

	public PrimitiveTypeLatticeElement asPrimitiveTypeLatticeElement() {
	return null;
	}

	public boolean isSingle() {
	return false;
	}

	public boolean isWide() {
	return false;
	}

	public boolean isInt() {
	return false;
	}

	public boolean isFloat() {
	return false;
	}

	public boolean isLong() {
	return false;
	}

	public boolean isDouble() {
	return false;
	}

	public boolean isPreciseType() {
	return isArrayType()
	\|\| isClassType()
	\|\| isNull()
	\|\| isInt()
	\|\| isFloat()
	\|\| isLong()
	\|\| isDouble()
	\|\| isBottom();
	}

	/**
	* Should use {@link #isConstantNull()} or {@link #isDefinitelyNull()} instead.
	*/
	@Deprecated
	public boolean isNull() {
	return false;
	}

	/**
	* Determines if this type only includes null values that are defined by a const-number
	* instruction in the same enclosing method.
	*
	* These null values can be assigned to any type.
	*/
	public boolean isConstantNull() {
	return isNull();
	}

	/**
	* Determines if this type only includes null values.
	*
	* These null values cannot be assigned to any type. For example, it is a type error to "throw v"
	* where the value `v` satisfies isDefinitelyNull(), because the static type of `v` may not be a
	* subtype of Throwable.
	*/
	public boolean isDefinitelyNull() {
	return nullElement().isDefinitelyNull();
	}

	public int requiredRegisters() {
	assert !isBottom() && !isTop();
	return isWide() ? 2 : 1;
	}

	static TypeLatticeElement objectClassType(AppInfo appInfo, boolean isNullable) {
	return fromDexType(appInfo.dexItemFactory.objectType, isNullable, appInfo);
	}

	static TypeLatticeElement objectArrayType(AppInfo appInfo, int nesting, boolean isNullable) {
	return fromDexType(
	appInfo.dexItemFactory.createArrayType(nesting, appInfo.dexItemFactory.objectType),
	isNullable, appInfo);
	}

	public static TypeLatticeElement classClassType(AppInfo appInfo) {
	return fromDexType(appInfo.dexItemFactory.classType, false, appInfo);
	}

	public static TypeLatticeElement stringClassType(AppInfo appInfo) {
	return fromDexType(appInfo.dexItemFactory.stringType, false, appInfo);
	}

	public static TypeLatticeElement fromDexType(DexType type, boolean isNullable, AppInfo appInfo) {
	if (type == DexItemFactory.nullValueType) {
	return NULL;
	}
	if (type.isPrimitiveType()) {
	return PrimitiveTypeLatticeElement.fromDexType(type);
	}
	return appInfo.dexItemFactory.createReferenceTypeLatticeElement(type, isNullable, appInfo);
	}

	public static TypeLatticeElement fromNumericType(NumericType type) {
	switch (type) {
	case BYTE:
	case CHAR:
	case SHORT:
	case INT:
	return INT;
	case LONG:
	return LONG;
	case FLOAT:
	return FLOAT;
	case DOUBLE:
	return DOUBLE;
	default:
	throw new Unreachable("Unexpected numeric type: " + type);
	}
	}

	public boolean isValueTypeCompatible(TypeLatticeElement other) {
	return (isReference() && other.isReference())
	\|\| (isSingle() && other.isSingle())
	\|\| (isWide() && other.isWide());
	}

	public static TypeLatticeElement newArray(DexType arrayType, boolean isNullable) {
	return new ArrayTypeLatticeElement(arrayType, isNullable);
	}

	public TypeLatticeElement arrayGet(AppInfo appInfo) {
	return BOTTOM;
	}

	public TypeLatticeElement checkCast(AppInfo appInfo, DexType castType) {
	TypeLatticeElement castTypeLattice = fromDexType(castType, isNullable(), appInfo);
	if (lessThanOrEqual(castTypeLattice, appInfo)) {
	return this;
	}
	return castTypeLattice;
	}

	@Override
	public abstract String toString();

	@Override
	public abstract boolean equals(Object o);

	@Override
	public abstract int hashCode();
	}