001/* 002 * Copyright (C) 2006 The Guava Authors 003 * 004 * Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except 005 * in compliance with the License. You may obtain a copy of the License at 006 * 007 * http://www.apache.org/licenses/LICENSE-2.0 008 * 009 * Unless required by applicable law or agreed to in writing, software distributed under the License 010 * is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express 011 * or implied. See the License for the specific language governing permissions and limitations under 012 * the License. 013 */ 014 015package com.google.common.reflect; 016 017import static com.google.common.base.Preconditions.checkArgument; 018import static com.google.common.base.Preconditions.checkNotNull; 019import static com.google.common.base.Preconditions.checkState; 020 021import com.google.common.annotations.Beta; 022import com.google.common.annotations.VisibleForTesting; 023import com.google.common.base.Joiner; 024import com.google.common.base.Predicate; 025import com.google.common.collect.FluentIterable; 026import com.google.common.collect.ForwardingSet; 027import com.google.common.collect.ImmutableList; 028import com.google.common.collect.ImmutableMap; 029import com.google.common.collect.ImmutableSet; 030import com.google.common.collect.Maps; 031import com.google.common.collect.Ordering; 032import com.google.common.primitives.Primitives; 033import com.google.errorprone.annotations.CanIgnoreReturnValue; 034import java.io.Serializable; 035import java.lang.reflect.Constructor; 036import java.lang.reflect.GenericArrayType; 037import java.lang.reflect.Method; 038import java.lang.reflect.Modifier; 039import java.lang.reflect.ParameterizedType; 040import java.lang.reflect.Type; 041import java.lang.reflect.TypeVariable; 042import java.lang.reflect.WildcardType; 043import java.util.Arrays; 044import java.util.Comparator; 045import java.util.Map; 046import java.util.Set; 047import javax.annotation.Nullable; 048 049/** 050 * A {@link Type} with generics. 051 * 052 * <p>Operations that are otherwise only available in {@link Class} are implemented to support 053 * {@code Type}, for example {@link #isSubtypeOf}, {@link #isArray} and {@link #getComponentType}. 054 * It also provides additional utilities such as {@link #getTypes}, {@link #resolveType}, etc. 055 * 056 * <p>There are three ways to get a {@code TypeToken} instance: 057 * 058 * <ul> 059 * 060 * <li>Wrap a {@code Type} obtained via reflection. For example: 061 * {@code TypeToken.of(method.getGenericReturnType())}. 062 * 063 * <li>Capture a generic type with a (usually anonymous) subclass. For example: <pre> {@code 064 * new TypeToken<List<String>>() {}}</pre> 065 * 066 * <p>Note that it's critical that the actual type argument is carried by a subclass. The 067 * following code is wrong because it only captures the {@code <T>} type variable of the {@code 068 * listType()} method signature; while {@code <String>} is lost in erasure: 069 * 070 * <pre> {@code 071 * class Util { 072 * static <T> TypeToken<List<T>> listType() { 073 * return new TypeToken<List<T>>() {}; 074 * } 075 * } 076 * 077 * TypeToken<List<String>> stringListType = Util.<String>listType();}</pre> 078 * 079 * <li>Capture a generic type with a (usually anonymous) subclass and resolve it against a context 080 * class that knows what the type parameters are. For example: <pre> {@code 081 * abstract class IKnowMyType<T> { 082 * TypeToken<T> type = new TypeToken<T>(getClass()) {}; 083 * } 084 * new IKnowMyType<String>() {}.type => String}</pre> 085 * 086 * </ul> 087 * 088 * <p>{@code TypeToken} is serializable when no type variable is contained in the type. 089 * 090 * <p>Note to Guice users: {@code} TypeToken is similar to Guice's {@code TypeLiteral} class except 091 * that it is serializable and offers numerous additional utility methods. 092 * 093 * @author Bob Lee 094 * @author Sven Mawson 095 * @author Ben Yu 096 * @since 12.0 097 */ 098@Beta 099@SuppressWarnings("serial") // SimpleTypeToken is the serialized form. 100public abstract class TypeToken<T> extends TypeCapture<T> implements Serializable { 101 102 private final Type runtimeType; 103 104 /** Resolver for resolving types with {@link #runtimeType} as context. */ 105 private transient TypeResolver typeResolver; 106 107 /** 108 * Constructs a new type token of {@code T}. 109 * 110 * <p>Clients create an empty anonymous subclass. Doing so embeds the type parameter in the 111 * anonymous class's type hierarchy so we can reconstitute it at runtime despite erasure. 112 * 113 * <p>For example: <pre> {@code 114 * TypeToken<List<String>> t = new TypeToken<List<String>>() {};}</pre> 115 */ 116 protected TypeToken() { 117 this.runtimeType = capture(); 118 checkState( 119 !(runtimeType instanceof TypeVariable), 120 "Cannot construct a TypeToken for a type variable.\n" 121 + "You probably meant to call new TypeToken<%s>(getClass()) " 122 + "that can resolve the type variable for you.\n" 123 + "If you do need to create a TypeToken of a type variable, " 124 + "please use TypeToken.of() instead.", 125 runtimeType); 126 } 127 128 /** 129 * Constructs a new type token of {@code T} while resolving free type variables in the context of 130 * {@code declaringClass}. 131 * 132 * <p>Clients create an empty anonymous subclass. Doing so embeds the type parameter in the 133 * anonymous class's type hierarchy so we can reconstitute it at runtime despite erasure. 134 * 135 * <p>For example: <pre> {@code 136 * abstract class IKnowMyType<T> { 137 * TypeToken<T> getMyType() { 138 * return new TypeToken<T>(getClass()) {}; 139 * } 140 * } 141 * 142 * new IKnowMyType<String>() {}.getMyType() => String}</pre> 143 */ 144 protected TypeToken(Class<?> declaringClass) { 145 Type captured = super.capture(); 146 if (captured instanceof Class) { 147 this.runtimeType = captured; 148 } else { 149 this.runtimeType = of(declaringClass).resolveType(captured).runtimeType; 150 } 151 } 152 153 private TypeToken(Type type) { 154 this.runtimeType = checkNotNull(type); 155 } 156 157 /** Returns an instance of type token that wraps {@code type}. */ 158 public static <T> TypeToken<T> of(Class<T> type) { 159 return new SimpleTypeToken<T>(type); 160 } 161 162 /** Returns an instance of type token that wraps {@code type}. */ 163 public static TypeToken<?> of(Type type) { 164 return new SimpleTypeToken<>(type); 165 } 166 167 /** 168 * Returns the raw type of {@code T}. Formally speaking, if {@code T} is returned by 169 * {@link java.lang.reflect.Method#getGenericReturnType}, the raw type is what's returned by 170 * {@link java.lang.reflect.Method#getReturnType} of the same method object. Specifically: 171 * <ul> 172 * <li>If {@code T} is a {@code Class} itself, {@code T} itself is returned. 173 * <li>If {@code T} is a {@link ParameterizedType}, the raw type of the parameterized type is 174 * returned. 175 * <li>If {@code T} is a {@link GenericArrayType}, the returned type is the corresponding array 176 * class. For example: {@code List<Integer>[] => List[]}. 177 * <li>If {@code T} is a type variable or a wildcard type, the raw type of the first upper bound 178 * is returned. For example: {@code <X extends Foo> => Foo}. 179 * </ul> 180 */ 181 public final Class<? super T> getRawType() { 182 // For wildcard or type variable, the first bound determines the runtime type. 183 Class<?> rawType = getRawTypes().iterator().next(); 184 @SuppressWarnings("unchecked") // raw type is |T| 185 Class<? super T> result = (Class<? super T>) rawType; 186 return result; 187 } 188 189 /** Returns the represented type. */ 190 public final Type getType() { 191 return runtimeType; 192 } 193 194 /** 195 * <p>Returns a new {@code TypeToken} where type variables represented by {@code typeParam} are 196 * substituted by {@code typeArg}. For example, it can be used to construct {@code Map<K, V>} for 197 * any {@code K} and {@code V} type: <pre> {@code 198 * static <K, V> TypeToken<Map<K, V>> mapOf( 199 * TypeToken<K> keyType, TypeToken<V> valueType) { 200 * return new TypeToken<Map<K, V>>() {} 201 * .where(new TypeParameter<K>() {}, keyType) 202 * .where(new TypeParameter<V>() {}, valueType); 203 * }}</pre> 204 * 205 * @param <X> The parameter type 206 * @param typeParam the parameter type variable 207 * @param typeArg the actual type to substitute 208 */ 209 public final <X> TypeToken<T> where(TypeParameter<X> typeParam, TypeToken<X> typeArg) { 210 TypeResolver resolver = 211 new TypeResolver() 212 .where( 213 ImmutableMap.of( 214 new TypeResolver.TypeVariableKey(typeParam.typeVariable), typeArg.runtimeType)); 215 // If there's any type error, we'd report now rather than later. 216 return new SimpleTypeToken<T>(resolver.resolveType(runtimeType)); 217 } 218 219 /** 220 * <p>Returns a new {@code TypeToken} where type variables represented by {@code typeParam} are 221 * substituted by {@code typeArg}. For example, it can be used to construct {@code Map<K, V>} for 222 * any {@code K} and {@code V} type: <pre> {@code 223 * static <K, V> TypeToken<Map<K, V>> mapOf( 224 * Class<K> keyType, Class<V> valueType) { 225 * return new TypeToken<Map<K, V>>() {} 226 * .where(new TypeParameter<K>() {}, keyType) 227 * .where(new TypeParameter<V>() {}, valueType); 228 * }}</pre> 229 * 230 * @param <X> The parameter type 231 * @param typeParam the parameter type variable 232 * @param typeArg the actual type to substitute 233 */ 234 public final <X> TypeToken<T> where(TypeParameter<X> typeParam, Class<X> typeArg) { 235 return where(typeParam, of(typeArg)); 236 } 237 238 /** 239 * <p>Resolves the given {@code type} against the type context represented by this type. For 240 * example: <pre> {@code 241 * new TypeToken<List<String>>() {}.resolveType( 242 * List.class.getMethod("get", int.class).getGenericReturnType()) 243 * => String.class}</pre> 244 */ 245 public final TypeToken<?> resolveType(Type type) { 246 checkNotNull(type); 247 TypeResolver resolver = typeResolver; 248 if (resolver == null) { 249 resolver = (typeResolver = TypeResolver.accordingTo(runtimeType)); 250 } 251 return of(resolver.resolveType(type)); 252 } 253 254 private Type[] resolveInPlace(Type[] types) { 255 for (int i = 0; i < types.length; i++) { 256 types[i] = resolveType(types[i]).getType(); 257 } 258 return types; 259 } 260 261 private TypeToken<?> resolveSupertype(Type type) { 262 TypeToken<?> supertype = resolveType(type); 263 // super types' type mapping is a subset of type mapping of this type. 264 supertype.typeResolver = typeResolver; 265 return supertype; 266 } 267 268 /** 269 * Returns the generic superclass of this type or {@code null} if the type represents 270 * {@link Object} or an interface. This method is similar but different from 271 * {@link Class#getGenericSuperclass}. For example, {@code new TypeToken<StringArrayList>() 272 * {}.getGenericSuperclass()} will return {@code new TypeToken<ArrayList<String>>() {}}; while 273 * {@code StringArrayList.class.getGenericSuperclass()} will return {@code ArrayList<E>}, where 274 * {@code E} is the type variable declared by class {@code ArrayList}. 275 * 276 * <p>If this type is a type variable or wildcard, its first upper bound is examined and returned 277 * if the bound is a class or extends from a class. This means that the returned type could be a 278 * type variable too. 279 */ 280 @Nullable 281 final TypeToken<? super T> getGenericSuperclass() { 282 if (runtimeType instanceof TypeVariable) { 283 // First bound is always the super class, if one exists. 284 return boundAsSuperclass(((TypeVariable<?>) runtimeType).getBounds()[0]); 285 } 286 if (runtimeType instanceof WildcardType) { 287 // wildcard has one and only one upper bound. 288 return boundAsSuperclass(((WildcardType) runtimeType).getUpperBounds()[0]); 289 } 290 Type superclass = getRawType().getGenericSuperclass(); 291 if (superclass == null) { 292 return null; 293 } 294 @SuppressWarnings("unchecked") // super class of T 295 TypeToken<? super T> superToken = (TypeToken<? super T>) resolveSupertype(superclass); 296 return superToken; 297 } 298 299 @Nullable 300 private TypeToken<? super T> boundAsSuperclass(Type bound) { 301 TypeToken<?> token = of(bound); 302 if (token.getRawType().isInterface()) { 303 return null; 304 } 305 @SuppressWarnings("unchecked") // only upper bound of T is passed in. 306 TypeToken<? super T> superclass = (TypeToken<? super T>) token; 307 return superclass; 308 } 309 310 /** 311 * Returns the generic interfaces that this type directly {@code implements}. This method is 312 * similar but different from {@link Class#getGenericInterfaces()}. For example, {@code new 313 * TypeToken<List<String>>() {}.getGenericInterfaces()} will return a list that contains 314 * {@code new TypeToken<Iterable<String>>() {}}; while {@code List.class.getGenericInterfaces()} 315 * will return an array that contains {@code Iterable<T>}, where the {@code T} is the type 316 * variable declared by interface {@code Iterable}. 317 * 318 * <p>If this type is a type variable or wildcard, its upper bounds are examined and those that 319 * are either an interface or upper-bounded only by interfaces are returned. This means that the 320 * returned types could include type variables too. 321 */ 322 final ImmutableList<TypeToken<? super T>> getGenericInterfaces() { 323 if (runtimeType instanceof TypeVariable) { 324 return boundsAsInterfaces(((TypeVariable<?>) runtimeType).getBounds()); 325 } 326 if (runtimeType instanceof WildcardType) { 327 return boundsAsInterfaces(((WildcardType) runtimeType).getUpperBounds()); 328 } 329 ImmutableList.Builder<TypeToken<? super T>> builder = ImmutableList.builder(); 330 for (Type interfaceType : getRawType().getGenericInterfaces()) { 331 @SuppressWarnings("unchecked") // interface of T 332 TypeToken<? super T> resolvedInterface = 333 (TypeToken<? super T>) resolveSupertype(interfaceType); 334 builder.add(resolvedInterface); 335 } 336 return builder.build(); 337 } 338 339 private ImmutableList<TypeToken<? super T>> boundsAsInterfaces(Type[] bounds) { 340 ImmutableList.Builder<TypeToken<? super T>> builder = ImmutableList.builder(); 341 for (Type bound : bounds) { 342 @SuppressWarnings("unchecked") // upper bound of T 343 TypeToken<? super T> boundType = (TypeToken<? super T>) of(bound); 344 if (boundType.getRawType().isInterface()) { 345 builder.add(boundType); 346 } 347 } 348 return builder.build(); 349 } 350 351 /** 352 * Returns the set of interfaces and classes that this type is or is a subtype of. The returned 353 * types are parameterized with proper type arguments. 354 * 355 * <p>Subtypes are always listed before supertypes. But the reverse is not true. A type isn't 356 * necessarily a subtype of all the types following. Order between types without subtype 357 * relationship is arbitrary and not guaranteed. 358 * 359 * <p>If this type is a type variable or wildcard, upper bounds that are themselves type variables 360 * aren't included (their super interfaces and superclasses are). 361 */ 362 public final TypeSet getTypes() { 363 return new TypeSet(); 364 } 365 366 /** 367 * Returns the generic form of {@code superclass}. For example, if this is 368 * {@code ArrayList<String>}, {@code Iterable<String>} is returned given the input 369 * {@code Iterable.class}. 370 */ 371 public final TypeToken<? super T> getSupertype(Class<? super T> superclass) { 372 checkArgument( 373 this.someRawTypeIsSubclassOf(superclass), 374 "%s is not a super class of %s", 375 superclass, 376 this); 377 if (runtimeType instanceof TypeVariable) { 378 return getSupertypeFromUpperBounds(superclass, ((TypeVariable<?>) runtimeType).getBounds()); 379 } 380 if (runtimeType instanceof WildcardType) { 381 return getSupertypeFromUpperBounds(superclass, ((WildcardType) runtimeType).getUpperBounds()); 382 } 383 if (superclass.isArray()) { 384 return getArraySupertype(superclass); 385 } 386 @SuppressWarnings("unchecked") // resolved supertype 387 TypeToken<? super T> supertype = 388 (TypeToken<? super T>) resolveSupertype(toGenericType(superclass).runtimeType); 389 return supertype; 390 } 391 392 /** 393 * Returns subtype of {@code this} with {@code subclass} as the raw class. For example, if this is 394 * {@code Iterable<String>} and {@code subclass} is {@code List}, {@code List<String>} is 395 * returned. 396 */ 397 public final TypeToken<? extends T> getSubtype(Class<?> subclass) { 398 checkArgument( 399 !(runtimeType instanceof TypeVariable), "Cannot get subtype of type variable <%s>", this); 400 if (runtimeType instanceof WildcardType) { 401 return getSubtypeFromLowerBounds(subclass, ((WildcardType) runtimeType).getLowerBounds()); 402 } 403 // unwrap array type if necessary 404 if (isArray()) { 405 return getArraySubtype(subclass); 406 } 407 // At this point, it's either a raw class or parameterized type. 408 checkArgument( 409 getRawType().isAssignableFrom(subclass), "%s isn't a subclass of %s", subclass, this); 410 Type resolvedTypeArgs = resolveTypeArgsForSubclass(subclass); 411 @SuppressWarnings("unchecked") // guarded by the isAssignableFrom() statement above 412 TypeToken<? extends T> subtype = (TypeToken<? extends T>) of(resolvedTypeArgs); 413 return subtype; 414 } 415 416 /** 417 * Returns true if this type is a supertype of the given {@code type}. "Supertype" is defined 418 * according to 419 * <a href="http://docs.oracle.com/javase/specs/jls/se8/html/jls-4.html#jls-4.5.1">the rules for 420 * type arguments</a> introduced with Java generics. 421 * 422 * @since 19.0 423 */ 424 public final boolean isSupertypeOf(TypeToken<?> type) { 425 return type.isSubtypeOf(getType()); 426 } 427 428 /** 429 * Returns true if this type is a supertype of the given {@code type}. "Supertype" is defined 430 * according to 431 * <a href="http://docs.oracle.com/javase/specs/jls/se8/html/jls-4.html#jls-4.5.1">the rules for 432 * type arguments</a> introduced with Java generics. 433 * 434 * @since 19.0 435 */ 436 public final boolean isSupertypeOf(Type type) { 437 return of(type).isSubtypeOf(getType()); 438 } 439 440 /** 441 * Returns true if this type is a subtype of the given {@code type}. "Subtype" is defined 442 * according to 443 * <a href="http://docs.oracle.com/javase/specs/jls/se8/html/jls-4.html#jls-4.5.1">the rules for 444 * type arguments</a> introduced with Java generics. 445 * 446 * @since 19.0 447 */ 448 public final boolean isSubtypeOf(TypeToken<?> type) { 449 return isSubtypeOf(type.getType()); 450 } 451 452 /** 453 * Returns true if this type is a subtype of the given {@code type}. "Subtype" is defined 454 * according to 455 * <a href="http://docs.oracle.com/javase/specs/jls/se8/html/jls-4.html#jls-4.5.1">the rules for 456 * type arguments</a> introduced with Java generics. 457 * 458 * @since 19.0 459 */ 460 public final boolean isSubtypeOf(Type supertype) { 461 checkNotNull(supertype); 462 if (supertype instanceof WildcardType) { 463 // if 'supertype' is <? super Foo>, 'this' can be: 464 // Foo, SubFoo, <? extends Foo>. 465 // if 'supertype' is <? extends Foo>, nothing is a subtype. 466 return any(((WildcardType) supertype).getLowerBounds()).isSupertypeOf(runtimeType); 467 } 468 // if 'this' is wildcard, it's a suptype of to 'supertype' if any of its "extends" 469 // bounds is a subtype of 'supertype'. 470 if (runtimeType instanceof WildcardType) { 471 // <? super Base> is of no use in checking 'from' being a subtype of 'to'. 472 return any(((WildcardType) runtimeType).getUpperBounds()).isSubtypeOf(supertype); 473 } 474 // if 'this' is type variable, it's a subtype if any of its "extends" 475 // bounds is a subtype of 'supertype'. 476 if (runtimeType instanceof TypeVariable) { 477 return runtimeType.equals(supertype) 478 || any(((TypeVariable<?>) runtimeType).getBounds()).isSubtypeOf(supertype); 479 } 480 if (runtimeType instanceof GenericArrayType) { 481 return of(supertype).isSupertypeOfArray((GenericArrayType) runtimeType); 482 } 483 // Proceed to regular Type subtype check 484 if (supertype instanceof Class) { 485 return this.someRawTypeIsSubclassOf((Class<?>) supertype); 486 } else if (supertype instanceof ParameterizedType) { 487 return this.isSubtypeOfParameterizedType((ParameterizedType) supertype); 488 } else if (supertype instanceof GenericArrayType) { 489 return this.isSubtypeOfArrayType((GenericArrayType) supertype); 490 } else { // to instanceof TypeVariable 491 return false; 492 } 493 } 494 495 /** 496 * Returns true if this type is known to be an array type, such as {@code int[]}, {@code T[]}, 497 * {@code <? extends Map<String, Integer>[]>} etc. 498 */ 499 public final boolean isArray() { 500 return getComponentType() != null; 501 } 502 503 /** 504 * Returns true if this type is one of the nine primitive types (including {@code void}). 505 * 506 * @since 15.0 507 */ 508 public final boolean isPrimitive() { 509 return (runtimeType instanceof Class) && ((Class<?>) runtimeType).isPrimitive(); 510 } 511 512 /** 513 * Returns the corresponding wrapper type if this is a primitive type; otherwise returns 514 * {@code this} itself. Idempotent. 515 * 516 * @since 15.0 517 */ 518 public final TypeToken<T> wrap() { 519 if (isPrimitive()) { 520 @SuppressWarnings("unchecked") // this is a primitive class 521 Class<T> type = (Class<T>) runtimeType; 522 return of(Primitives.wrap(type)); 523 } 524 return this; 525 } 526 527 private boolean isWrapper() { 528 return Primitives.allWrapperTypes().contains(runtimeType); 529 } 530 531 /** 532 * Returns the corresponding primitive type if this is a wrapper type; otherwise returns 533 * {@code this} itself. Idempotent. 534 * 535 * @since 15.0 536 */ 537 public final TypeToken<T> unwrap() { 538 if (isWrapper()) { 539 @SuppressWarnings("unchecked") // this is a wrapper class 540 Class<T> type = (Class<T>) runtimeType; 541 return of(Primitives.unwrap(type)); 542 } 543 return this; 544 } 545 546 /** 547 * Returns the array component type if this type represents an array ({@code int[]}, {@code T[]}, 548 * {@code <? extends Map<String, Integer>[]>} etc.), or else {@code null} is returned. 549 */ 550 @Nullable 551 public final TypeToken<?> getComponentType() { 552 Type componentType = Types.getComponentType(runtimeType); 553 if (componentType == null) { 554 return null; 555 } 556 return of(componentType); 557 } 558 559 /** 560 * Returns the {@link Invokable} for {@code method}, which must be a member of {@code T}. 561 * 562 * @since 14.0 563 */ 564 public final Invokable<T, Object> method(Method method) { 565 checkArgument( 566 this.someRawTypeIsSubclassOf(method.getDeclaringClass()), 567 "%s not declared by %s", 568 method, 569 this); 570 return new Invokable.MethodInvokable<T>(method) { 571 @Override 572 Type getGenericReturnType() { 573 return resolveType(super.getGenericReturnType()).getType(); 574 } 575 576 @Override 577 Type[] getGenericParameterTypes() { 578 return resolveInPlace(super.getGenericParameterTypes()); 579 } 580 581 @Override 582 Type[] getGenericExceptionTypes() { 583 return resolveInPlace(super.getGenericExceptionTypes()); 584 } 585 586 @Override 587 public TypeToken<T> getOwnerType() { 588 return TypeToken.this; 589 } 590 591 @Override 592 public String toString() { 593 return getOwnerType() + "." + super.toString(); 594 } 595 }; 596 } 597 598 /** 599 * Returns the {@link Invokable} for {@code constructor}, which must be a member of {@code T}. 600 * 601 * @since 14.0 602 */ 603 public final Invokable<T, T> constructor(Constructor<?> constructor) { 604 checkArgument( 605 constructor.getDeclaringClass() == getRawType(), 606 "%s not declared by %s", 607 constructor, 608 getRawType()); 609 return new Invokable.ConstructorInvokable<T>(constructor) { 610 @Override 611 Type getGenericReturnType() { 612 return resolveType(super.getGenericReturnType()).getType(); 613 } 614 615 @Override 616 Type[] getGenericParameterTypes() { 617 return resolveInPlace(super.getGenericParameterTypes()); 618 } 619 620 @Override 621 Type[] getGenericExceptionTypes() { 622 return resolveInPlace(super.getGenericExceptionTypes()); 623 } 624 625 @Override 626 public TypeToken<T> getOwnerType() { 627 return TypeToken.this; 628 } 629 630 @Override 631 public String toString() { 632 return getOwnerType() + "(" + Joiner.on(", ").join(getGenericParameterTypes()) + ")"; 633 } 634 }; 635 } 636 637 /** 638 * The set of interfaces and classes that {@code T} is or is a subtype of. {@link Object} is not 639 * included in the set if this type is an interface. 640 */ 641 public class TypeSet extends ForwardingSet<TypeToken<? super T>> implements Serializable { 642 643 private transient ImmutableSet<TypeToken<? super T>> types; 644 645 TypeSet() {} 646 647 /** Returns the types that are interfaces implemented by this type. */ 648 public TypeSet interfaces() { 649 return new InterfaceSet(this); 650 } 651 652 /** Returns the types that are classes. */ 653 public TypeSet classes() { 654 return new ClassSet(); 655 } 656 657 @Override 658 protected Set<TypeToken<? super T>> delegate() { 659 ImmutableSet<TypeToken<? super T>> filteredTypes = types; 660 if (filteredTypes == null) { 661 // Java has no way to express ? super T when we parameterize TypeToken vs. Class. 662 @SuppressWarnings({"unchecked", "rawtypes"}) 663 ImmutableList<TypeToken<? super T>> collectedTypes = 664 (ImmutableList) TypeCollector.FOR_GENERIC_TYPE.collectTypes(TypeToken.this); 665 return (types = 666 FluentIterable.from(collectedTypes) 667 .filter(TypeFilter.IGNORE_TYPE_VARIABLE_OR_WILDCARD) 668 .toSet()); 669 } else { 670 return filteredTypes; 671 } 672 } 673 674 /** Returns the raw types of the types in this set, in the same order. */ 675 public Set<Class<? super T>> rawTypes() { 676 // Java has no way to express ? super T when we parameterize TypeToken vs. Class. 677 @SuppressWarnings({"unchecked", "rawtypes"}) 678 ImmutableList<Class<? super T>> collectedTypes = 679 (ImmutableList) TypeCollector.FOR_RAW_TYPE.collectTypes(getRawTypes()); 680 return ImmutableSet.copyOf(collectedTypes); 681 } 682 683 private static final long serialVersionUID = 0; 684 } 685 686 private final class InterfaceSet extends TypeSet { 687 688 private final transient TypeSet allTypes; 689 private transient ImmutableSet<TypeToken<? super T>> interfaces; 690 691 InterfaceSet(TypeSet allTypes) { 692 this.allTypes = allTypes; 693 } 694 695 @Override 696 protected Set<TypeToken<? super T>> delegate() { 697 ImmutableSet<TypeToken<? super T>> result = interfaces; 698 if (result == null) { 699 return (interfaces = 700 FluentIterable.from(allTypes).filter(TypeFilter.INTERFACE_ONLY).toSet()); 701 } else { 702 return result; 703 } 704 } 705 706 @Override 707 public TypeSet interfaces() { 708 return this; 709 } 710 711 @Override 712 public Set<Class<? super T>> rawTypes() { 713 // Java has no way to express ? super T when we parameterize TypeToken vs. Class. 714 @SuppressWarnings({"unchecked", "rawtypes"}) 715 ImmutableList<Class<? super T>> collectedTypes = 716 (ImmutableList) TypeCollector.FOR_RAW_TYPE.collectTypes(getRawTypes()); 717 return FluentIterable.from(collectedTypes) 718 .filter( 719 new Predicate<Class<?>>() { 720 @Override 721 public boolean apply(Class<?> type) { 722 return type.isInterface(); 723 } 724 }) 725 .toSet(); 726 } 727 728 @Override 729 public TypeSet classes() { 730 throw new UnsupportedOperationException("interfaces().classes() not supported."); 731 } 732 733 private Object readResolve() { 734 return getTypes().interfaces(); 735 } 736 737 private static final long serialVersionUID = 0; 738 } 739 740 private final class ClassSet extends TypeSet { 741 742 private transient ImmutableSet<TypeToken<? super T>> classes; 743 744 @Override 745 protected Set<TypeToken<? super T>> delegate() { 746 ImmutableSet<TypeToken<? super T>> result = classes; 747 if (result == null) { 748 @SuppressWarnings({"unchecked", "rawtypes"}) 749 ImmutableList<TypeToken<? super T>> collectedTypes = 750 (ImmutableList) 751 TypeCollector.FOR_GENERIC_TYPE.classesOnly().collectTypes(TypeToken.this); 752 return (classes = 753 FluentIterable.from(collectedTypes) 754 .filter(TypeFilter.IGNORE_TYPE_VARIABLE_OR_WILDCARD) 755 .toSet()); 756 } else { 757 return result; 758 } 759 } 760 761 @Override 762 public TypeSet classes() { 763 return this; 764 } 765 766 @Override 767 public Set<Class<? super T>> rawTypes() { 768 // Java has no way to express ? super T when we parameterize TypeToken vs. Class. 769 @SuppressWarnings({"unchecked", "rawtypes"}) 770 ImmutableList<Class<? super T>> collectedTypes = 771 (ImmutableList) TypeCollector.FOR_RAW_TYPE.classesOnly().collectTypes(getRawTypes()); 772 return ImmutableSet.copyOf(collectedTypes); 773 } 774 775 @Override 776 public TypeSet interfaces() { 777 throw new UnsupportedOperationException("classes().interfaces() not supported."); 778 } 779 780 private Object readResolve() { 781 return getTypes().classes(); 782 } 783 784 private static final long serialVersionUID = 0; 785 } 786 787 private enum TypeFilter implements Predicate<TypeToken<?>> { 788 IGNORE_TYPE_VARIABLE_OR_WILDCARD { 789 @Override 790 public boolean apply(TypeToken<?> type) { 791 return !(type.runtimeType instanceof TypeVariable 792 || type.runtimeType instanceof WildcardType); 793 } 794 }, 795 INTERFACE_ONLY { 796 @Override 797 public boolean apply(TypeToken<?> type) { 798 return type.getRawType().isInterface(); 799 } 800 } 801 } 802 803 /** 804 * Returns true if {@code o} is another {@code TypeToken} that represents the same {@link Type}. 805 */ 806 @Override 807 public boolean equals(@Nullable Object o) { 808 if (o instanceof TypeToken) { 809 TypeToken<?> that = (TypeToken<?>) o; 810 return runtimeType.equals(that.runtimeType); 811 } 812 return false; 813 } 814 815 @Override 816 public int hashCode() { 817 return runtimeType.hashCode(); 818 } 819 820 @Override 821 public String toString() { 822 return Types.toString(runtimeType); 823 } 824 825 /** Implemented to support serialization of subclasses. */ 826 protected Object writeReplace() { 827 // TypeResolver just transforms the type to our own impls that are Serializable 828 // except TypeVariable. 829 return of(new TypeResolver().resolveType(runtimeType)); 830 } 831 832 /** 833 * Ensures that this type token doesn't contain type variables, which can cause unchecked type 834 * errors for callers like {@link TypeToInstanceMap}. 835 */ 836 @CanIgnoreReturnValue 837 final TypeToken<T> rejectTypeVariables() { 838 new TypeVisitor() { 839 @Override 840 void visitTypeVariable(TypeVariable<?> type) { 841 throw new IllegalArgumentException( 842 runtimeType + "contains a type variable and is not safe for the operation"); 843 } 844 845 @Override 846 void visitWildcardType(WildcardType type) { 847 visit(type.getLowerBounds()); 848 visit(type.getUpperBounds()); 849 } 850 851 @Override 852 void visitParameterizedType(ParameterizedType type) { 853 visit(type.getActualTypeArguments()); 854 visit(type.getOwnerType()); 855 } 856 857 @Override 858 void visitGenericArrayType(GenericArrayType type) { 859 visit(type.getGenericComponentType()); 860 } 861 }.visit(runtimeType); 862 return this; 863 } 864 865 private boolean someRawTypeIsSubclassOf(Class<?> superclass) { 866 for (Class<?> rawType : getRawTypes()) { 867 if (superclass.isAssignableFrom(rawType)) { 868 return true; 869 } 870 } 871 return false; 872 } 873 874 private boolean isSubtypeOfParameterizedType(ParameterizedType supertype) { 875 Class<?> matchedClass = of(supertype).getRawType(); 876 if (!someRawTypeIsSubclassOf(matchedClass)) { 877 return false; 878 } 879 Type[] typeParams = matchedClass.getTypeParameters(); 880 Type[] toTypeArgs = supertype.getActualTypeArguments(); 881 for (int i = 0; i < typeParams.length; i++) { 882 // If 'supertype' is "List<? extends CharSequence>" 883 // and 'this' is StringArrayList, 884 // First step is to figure out StringArrayList "is-a" List<E> and <E> is 885 // String. 886 // typeParams[0] is E and fromTypeToken.get(typeParams[0]) will resolve to 887 // String. 888 // String is then matched against <? extends CharSequence>. 889 if (!resolveType(typeParams[i]).is(toTypeArgs[i])) { 890 return false; 891 } 892 } 893 // We only care about the case when the supertype is a non-static inner class 894 // in which case we need to make sure the subclass's owner type is a subtype of the 895 // supertype's owner. 896 return Modifier.isStatic(((Class<?>) supertype.getRawType()).getModifiers()) 897 || supertype.getOwnerType() == null 898 || isOwnedBySubtypeOf(supertype.getOwnerType()); 899 } 900 901 private boolean isSubtypeOfArrayType(GenericArrayType supertype) { 902 if (runtimeType instanceof Class) { 903 Class<?> fromClass = (Class<?>) runtimeType; 904 if (!fromClass.isArray()) { 905 return false; 906 } 907 return of(fromClass.getComponentType()).isSubtypeOf(supertype.getGenericComponentType()); 908 } else if (runtimeType instanceof GenericArrayType) { 909 GenericArrayType fromArrayType = (GenericArrayType) runtimeType; 910 return of(fromArrayType.getGenericComponentType()) 911 .isSubtypeOf(supertype.getGenericComponentType()); 912 } else { 913 return false; 914 } 915 } 916 917 private boolean isSupertypeOfArray(GenericArrayType subtype) { 918 if (runtimeType instanceof Class) { 919 Class<?> thisClass = (Class<?>) runtimeType; 920 if (!thisClass.isArray()) { 921 return thisClass.isAssignableFrom(Object[].class); 922 } 923 return of(subtype.getGenericComponentType()).isSubtypeOf(thisClass.getComponentType()); 924 } else if (runtimeType instanceof GenericArrayType) { 925 return of(subtype.getGenericComponentType()) 926 .isSubtypeOf(((GenericArrayType) runtimeType).getGenericComponentType()); 927 } else { 928 return false; 929 } 930 } 931 932 /** 933 * Return true if any of the following conditions is met: 934 * 935 * <ul> 936 * <li>'this' and {@code formalType} are equal 937 * <li>{@code formalType} is {@code <? extends Foo>} and 'this' is a subtype of {@code Foo} 938 * <li>{@code formalType} is {@code <? super Foo>} and 'this' is a supertype of {@code Foo} 939 * </ul> 940 */ 941 private boolean is(Type formalType) { 942 if (runtimeType.equals(formalType)) { 943 return true; 944 } 945 if (formalType instanceof WildcardType) { 946 // if "formalType" is <? extends Foo>, "this" can be: 947 // Foo, SubFoo, <? extends Foo>, <? extends SubFoo>, <T extends Foo> or 948 // <T extends SubFoo>. 949 // if "formalType" is <? super Foo>, "this" can be: 950 // Foo, SuperFoo, <? super Foo> or <? super SuperFoo>. 951 return every(((WildcardType) formalType).getUpperBounds()).isSupertypeOf(runtimeType) 952 && every(((WildcardType) formalType).getLowerBounds()).isSubtypeOf(runtimeType); 953 } 954 return false; 955 } 956 957 private static Bounds every(Type[] bounds) { 958 // Every bound must match. On any false, result is false. 959 return new Bounds(bounds, false); 960 } 961 962 private static Bounds any(Type[] bounds) { 963 // Any bound matches. On any true, result is true. 964 return new Bounds(bounds, true); 965 } 966 967 private static class Bounds { 968 private final Type[] bounds; 969 private final boolean target; 970 971 Bounds(Type[] bounds, boolean target) { 972 this.bounds = bounds; 973 this.target = target; 974 } 975 976 boolean isSubtypeOf(Type supertype) { 977 for (Type bound : bounds) { 978 if (of(bound).isSubtypeOf(supertype) == target) { 979 return target; 980 } 981 } 982 return !target; 983 } 984 985 boolean isSupertypeOf(Type subtype) { 986 TypeToken<?> type = of(subtype); 987 for (Type bound : bounds) { 988 if (type.isSubtypeOf(bound) == target) { 989 return target; 990 } 991 } 992 return !target; 993 } 994 } 995 996 private ImmutableSet<Class<? super T>> getRawTypes() { 997 final ImmutableSet.Builder<Class<?>> builder = ImmutableSet.builder(); 998 new TypeVisitor() { 999 @Override 1000 void visitTypeVariable(TypeVariable<?> t) { 1001 visit(t.getBounds()); 1002 } 1003 1004 @Override 1005 void visitWildcardType(WildcardType t) { 1006 visit(t.getUpperBounds()); 1007 } 1008 1009 @Override 1010 void visitParameterizedType(ParameterizedType t) { 1011 builder.add((Class<?>) t.getRawType()); 1012 } 1013 1014 @Override 1015 void visitClass(Class<?> t) { 1016 builder.add(t); 1017 } 1018 1019 @Override 1020 void visitGenericArrayType(GenericArrayType t) { 1021 builder.add(Types.getArrayClass(of(t.getGenericComponentType()).getRawType())); 1022 } 1023 }.visit(runtimeType); 1024 // Cast from ImmutableSet<Class<?>> to ImmutableSet<Class<? super T>> 1025 @SuppressWarnings({"unchecked", "rawtypes"}) 1026 ImmutableSet<Class<? super T>> result = (ImmutableSet) builder.build(); 1027 return result; 1028 } 1029 1030 private boolean isOwnedBySubtypeOf(Type supertype) { 1031 for (TypeToken<?> type : getTypes()) { 1032 Type ownerType = type.getOwnerTypeIfPresent(); 1033 if (ownerType != null && of(ownerType).isSubtypeOf(supertype)) { 1034 return true; 1035 } 1036 } 1037 return false; 1038 } 1039 1040 /** 1041 * Returns the owner type of a {@link ParameterizedType} or enclosing class of a {@link Class}, 1042 * or null otherwise. 1043 */ 1044 @Nullable private Type getOwnerTypeIfPresent() { 1045 if (runtimeType instanceof ParameterizedType) { 1046 return ((ParameterizedType) runtimeType).getOwnerType(); 1047 } else if (runtimeType instanceof Class<?>) { 1048 return ((Class<?>) runtimeType).getEnclosingClass(); 1049 } else { 1050 return null; 1051 } 1052 } 1053 1054 /** 1055 * Returns the type token representing the generic type declaration of {@code cls}. For example: 1056 * {@code TypeToken.getGenericType(Iterable.class)} returns {@code Iterable<T>}. 1057 * 1058 * <p>If {@code cls} isn't parameterized and isn't a generic array, the type token of the class is 1059 * returned. 1060 */ 1061 @VisibleForTesting 1062 static <T> TypeToken<? extends T> toGenericType(Class<T> cls) { 1063 if (cls.isArray()) { 1064 Type arrayOfGenericType = 1065 Types.newArrayType( 1066 // If we are passed with int[].class, don't turn it to GenericArrayType 1067 toGenericType(cls.getComponentType()).runtimeType); 1068 @SuppressWarnings("unchecked") // array is covariant 1069 TypeToken<? extends T> result = (TypeToken<? extends T>) of(arrayOfGenericType); 1070 return result; 1071 } 1072 TypeVariable<Class<T>>[] typeParams = cls.getTypeParameters(); 1073 Type ownerType = 1074 cls.isMemberClass() && !Modifier.isStatic(cls.getModifiers()) 1075 ? toGenericType(cls.getEnclosingClass()).runtimeType 1076 : null; 1077 1078 if ((typeParams.length > 0) || ((ownerType != null) && ownerType != cls.getEnclosingClass())) { 1079 @SuppressWarnings("unchecked") // Like, it's Iterable<T> for Iterable.class 1080 TypeToken<? extends T> type = 1081 (TypeToken<? extends T>) 1082 of(Types.newParameterizedTypeWithOwner(ownerType, cls, typeParams)); 1083 return type; 1084 } else { 1085 return of(cls); 1086 } 1087 } 1088 1089 private TypeToken<? super T> getSupertypeFromUpperBounds( 1090 Class<? super T> supertype, Type[] upperBounds) { 1091 for (Type upperBound : upperBounds) { 1092 @SuppressWarnings("unchecked") // T's upperbound is <? super T>. 1093 TypeToken<? super T> bound = (TypeToken<? super T>) of(upperBound); 1094 if (bound.isSubtypeOf(supertype)) { 1095 @SuppressWarnings({"rawtypes", "unchecked"}) // guarded by the isSubtypeOf check. 1096 TypeToken<? super T> result = bound.getSupertype((Class) supertype); 1097 return result; 1098 } 1099 } 1100 throw new IllegalArgumentException(supertype + " isn't a super type of " + this); 1101 } 1102 1103 private TypeToken<? extends T> getSubtypeFromLowerBounds(Class<?> subclass, Type[] lowerBounds) { 1104 for (Type lowerBound : lowerBounds) { 1105 @SuppressWarnings("unchecked") // T's lower bound is <? extends T> 1106 TypeToken<? extends T> bound = (TypeToken<? extends T>) of(lowerBound); 1107 // Java supports only one lowerbound anyway. 1108 return bound.getSubtype(subclass); 1109 } 1110 throw new IllegalArgumentException(subclass + " isn't a subclass of " + this); 1111 } 1112 1113 private TypeToken<? super T> getArraySupertype(Class<? super T> supertype) { 1114 // with component type, we have lost generic type information 1115 // Use raw type so that compiler allows us to call getSupertype() 1116 @SuppressWarnings("rawtypes") 1117 TypeToken componentType = 1118 checkNotNull(getComponentType(), "%s isn't a super type of %s", supertype, this); 1119 // array is covariant. component type is super type, so is the array type. 1120 @SuppressWarnings("unchecked") // going from raw type back to generics 1121 TypeToken<?> componentSupertype = componentType.getSupertype(supertype.getComponentType()); 1122 @SuppressWarnings("unchecked") // component type is super type, so is array type. 1123 TypeToken<? super T> result = 1124 (TypeToken<? super T>) 1125 // If we are passed with int[].class, don't turn it to GenericArrayType 1126 of(newArrayClassOrGenericArrayType(componentSupertype.runtimeType)); 1127 return result; 1128 } 1129 1130 private TypeToken<? extends T> getArraySubtype(Class<?> subclass) { 1131 // array is covariant. component type is subtype, so is the array type. 1132 TypeToken<?> componentSubtype = getComponentType().getSubtype(subclass.getComponentType()); 1133 @SuppressWarnings("unchecked") // component type is subtype, so is array type. 1134 TypeToken<? extends T> result = 1135 (TypeToken<? extends T>) 1136 // If we are passed with int[].class, don't turn it to GenericArrayType 1137 of(newArrayClassOrGenericArrayType(componentSubtype.runtimeType)); 1138 return result; 1139 } 1140 1141 private Type resolveTypeArgsForSubclass(Class<?> subclass) { 1142 // If both runtimeType and subclass are not parameterized, return subclass 1143 // If runtimeType is not parameterized but subclass is, process subclass as a parameterized type 1144 // If runtimeType is a raw type (i.e. is a parameterized type specified as a Class<?>), we 1145 // return subclass as a raw type 1146 if (runtimeType instanceof Class 1147 && ((subclass.getTypeParameters().length == 0) 1148 || (getRawType().getTypeParameters().length != 0))) { 1149 // no resolution needed 1150 return subclass; 1151 } 1152 // class Base<A, B> {} 1153 // class Sub<X, Y> extends Base<X, Y> {} 1154 // Base<String, Integer>.subtype(Sub.class): 1155 1156 // Sub<X, Y>.getSupertype(Base.class) => Base<X, Y> 1157 // => X=String, Y=Integer 1158 // => Sub<X, Y>=Sub<String, Integer> 1159 TypeToken<?> genericSubtype = toGenericType(subclass); 1160 @SuppressWarnings({"rawtypes", "unchecked"}) // subclass isn't <? extends T> 1161 Type supertypeWithArgsFromSubtype = 1162 genericSubtype.getSupertype((Class) getRawType()).runtimeType; 1163 return new TypeResolver() 1164 .where(supertypeWithArgsFromSubtype, runtimeType) 1165 .resolveType(genericSubtype.runtimeType); 1166 } 1167 1168 /** 1169 * Creates an array class if {@code componentType} is a class, or else, a 1170 * {@link GenericArrayType}. This is what Java7 does for generic array type parameters. 1171 */ 1172 private static Type newArrayClassOrGenericArrayType(Type componentType) { 1173 return Types.JavaVersion.JAVA7.newArrayType(componentType); 1174 } 1175 1176 private static final class SimpleTypeToken<T> extends TypeToken<T> { 1177 1178 SimpleTypeToken(Type type) { 1179 super(type); 1180 } 1181 1182 private static final long serialVersionUID = 0; 1183 } 1184 1185 /** 1186 * Collects parent types from a sub type. 1187 * 1188 * @param <K> The type "kind". Either a TypeToken, or Class. 1189 */ 1190 private abstract static class TypeCollector<K> { 1191 1192 static final TypeCollector<TypeToken<?>> FOR_GENERIC_TYPE = 1193 new TypeCollector<TypeToken<?>>() { 1194 @Override 1195 Class<?> getRawType(TypeToken<?> type) { 1196 return type.getRawType(); 1197 } 1198 1199 @Override 1200 Iterable<? extends TypeToken<?>> getInterfaces(TypeToken<?> type) { 1201 return type.getGenericInterfaces(); 1202 } 1203 1204 @Nullable 1205 @Override 1206 TypeToken<?> getSuperclass(TypeToken<?> type) { 1207 return type.getGenericSuperclass(); 1208 } 1209 }; 1210 1211 static final TypeCollector<Class<?>> FOR_RAW_TYPE = 1212 new TypeCollector<Class<?>>() { 1213 @Override 1214 Class<?> getRawType(Class<?> type) { 1215 return type; 1216 } 1217 1218 @Override 1219 Iterable<? extends Class<?>> getInterfaces(Class<?> type) { 1220 return Arrays.asList(type.getInterfaces()); 1221 } 1222 1223 @Nullable 1224 @Override 1225 Class<?> getSuperclass(Class<?> type) { 1226 return type.getSuperclass(); 1227 } 1228 }; 1229 1230 /** For just classes, we don't have to traverse interfaces. */ 1231 final TypeCollector<K> classesOnly() { 1232 return new ForwardingTypeCollector<K>(this) { 1233 @Override 1234 Iterable<? extends K> getInterfaces(K type) { 1235 return ImmutableSet.of(); 1236 } 1237 1238 @Override 1239 ImmutableList<K> collectTypes(Iterable<? extends K> types) { 1240 ImmutableList.Builder<K> builder = ImmutableList.builder(); 1241 for (K type : types) { 1242 if (!getRawType(type).isInterface()) { 1243 builder.add(type); 1244 } 1245 } 1246 return super.collectTypes(builder.build()); 1247 } 1248 }; 1249 } 1250 1251 final ImmutableList<K> collectTypes(K type) { 1252 return collectTypes(ImmutableList.of(type)); 1253 } 1254 1255 ImmutableList<K> collectTypes(Iterable<? extends K> types) { 1256 // type -> order number. 1 for Object, 2 for anything directly below, so on so forth. 1257 Map<K, Integer> map = Maps.newHashMap(); 1258 for (K type : types) { 1259 collectTypes(type, map); 1260 } 1261 return sortKeysByValue(map, Ordering.natural().reverse()); 1262 } 1263 1264 /** Collects all types to map, and returns the total depth from T up to Object. */ 1265 @CanIgnoreReturnValue 1266 private int collectTypes(K type, Map<? super K, Integer> map) { 1267 Integer existing = map.get(type); 1268 if (existing != null) { 1269 // short circuit: if set contains type it already contains its supertypes 1270 return existing; 1271 } 1272 // Interfaces should be listed before Object. 1273 int aboveMe = getRawType(type).isInterface() ? 1 : 0; 1274 for (K interfaceType : getInterfaces(type)) { 1275 aboveMe = Math.max(aboveMe, collectTypes(interfaceType, map)); 1276 } 1277 K superclass = getSuperclass(type); 1278 if (superclass != null) { 1279 aboveMe = Math.max(aboveMe, collectTypes(superclass, map)); 1280 } 1281 /* 1282 * TODO(benyu): should we include Object for interface? Also, CharSequence[] and Object[] for 1283 * String[]? 1284 * 1285 */ 1286 map.put(type, aboveMe + 1); 1287 return aboveMe + 1; 1288 } 1289 1290 private static <K, V> ImmutableList<K> sortKeysByValue( 1291 final Map<K, V> map, final Comparator<? super V> valueComparator) { 1292 Ordering<K> keyOrdering = 1293 new Ordering<K>() { 1294 @Override 1295 public int compare(K left, K right) { 1296 return valueComparator.compare(map.get(left), map.get(right)); 1297 } 1298 }; 1299 return keyOrdering.immutableSortedCopy(map.keySet()); 1300 } 1301 1302 abstract Class<?> getRawType(K type); 1303 1304 abstract Iterable<? extends K> getInterfaces(K type); 1305 1306 @Nullable 1307 abstract K getSuperclass(K type); 1308 1309 private static class ForwardingTypeCollector<K> extends TypeCollector<K> { 1310 1311 private final TypeCollector<K> delegate; 1312 1313 ForwardingTypeCollector(TypeCollector<K> delegate) { 1314 this.delegate = delegate; 1315 } 1316 1317 @Override 1318 Class<?> getRawType(K type) { 1319 return delegate.getRawType(type); 1320 } 1321 1322 @Override 1323 Iterable<? extends K> getInterfaces(K type) { 1324 return delegate.getInterfaces(type); 1325 } 1326 1327 @Override 1328 K getSuperclass(K type) { 1329 return delegate.getSuperclass(type); 1330 } 1331 } 1332 } 1333}