1 /* 2 * Copyright (c) 1994, 2024, Oracle and/or its affiliates. All rights reserved. 3 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. 4 * 5 * This code is free software; you can redistribute it and/or modify it 6 * under the terms of the GNU General Public License version 2 only, as 7 * published by the Free Software Foundation. Oracle designates this 8 * particular file as subject to the "Classpath" exception as provided 9 * by Oracle in the LICENSE file that accompanied this code. 10 * 11 * This code is distributed in the hope that it will be useful, but WITHOUT 12 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or 13 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License 14 * version 2 for more details (a copy is included in the LICENSE file that 15 * accompanied this code). 16 * 17 * You should have received a copy of the GNU General Public License version 18 * 2 along with this work; if not, write to the Free Software Foundation, 19 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. 20 * 21 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA 22 * or visit www.oracle.com if you need additional information or have any 23 * questions. 24 */ 25 26 package java.lang; 27 28 import java.lang.annotation.Annotation; 29 import java.lang.constant.ClassDesc; 30 import java.lang.constant.ConstantDescs; 31 import java.lang.invoke.TypeDescriptor; 32 import java.lang.invoke.MethodHandles; 33 import java.lang.module.ModuleReader; 34 import java.lang.ref.SoftReference; 35 import java.io.IOException; 36 import java.io.InputStream; 37 import java.io.ObjectStreamField; 38 import java.lang.reflect.AnnotatedElement; 39 import java.lang.reflect.AnnotatedType; 40 import java.lang.reflect.AccessFlag; 41 import java.lang.reflect.Array; 42 import java.lang.reflect.ClassFileFormatVersion; 43 import java.lang.reflect.Constructor; 44 import java.lang.reflect.Executable; 45 import java.lang.reflect.Field; 46 import java.lang.reflect.GenericArrayType; 47 import java.lang.reflect.GenericDeclaration; 48 import java.lang.reflect.InvocationTargetException; 49 import java.lang.reflect.Member; 50 import java.lang.reflect.Method; 51 import java.lang.reflect.Modifier; 52 import java.lang.reflect.Proxy; 53 import java.lang.reflect.RecordComponent; 54 import java.lang.reflect.Type; 55 import java.lang.reflect.TypeVariable; 56 import java.lang.constant.Constable; 57 import java.net.URL; 58 import java.security.AccessController; 59 import java.security.Permissions; 60 import java.security.PrivilegedAction; 61 import java.security.ProtectionDomain; 62 import java.util.ArrayList; 63 import java.util.Arrays; 64 import java.util.Collection; 65 import java.util.HashMap; 66 import java.util.HashSet; 67 import java.util.LinkedHashMap; 68 import java.util.LinkedHashSet; 69 import java.util.List; 70 import java.util.Map; 71 import java.util.Objects; 72 import java.util.Optional; 73 import java.util.Set; 74 import java.util.stream.Collectors; 75 76 import jdk.internal.constant.ConstantUtils; 77 import jdk.internal.javac.PreviewFeature; 78 import jdk.internal.loader.BootLoader; 79 import jdk.internal.loader.BuiltinClassLoader; 80 import jdk.internal.misc.PreviewFeatures; 81 import jdk.internal.misc.Unsafe; 82 import jdk.internal.module.Resources; 83 import jdk.internal.reflect.CallerSensitive; 84 import jdk.internal.reflect.CallerSensitiveAdapter; 85 import jdk.internal.reflect.ConstantPool; 86 import jdk.internal.reflect.Reflection; 87 import jdk.internal.reflect.ReflectionFactory; 88 import jdk.internal.vm.annotation.ForceInline; 89 import jdk.internal.vm.annotation.IntrinsicCandidate; 90 import jdk.internal.vm.annotation.Stable; 91 92 import sun.invoke.util.Wrapper; 93 import sun.reflect.generics.factory.CoreReflectionFactory; 94 import sun.reflect.generics.factory.GenericsFactory; 95 import sun.reflect.generics.repository.ClassRepository; 96 import sun.reflect.generics.repository.MethodRepository; 97 import sun.reflect.generics.repository.ConstructorRepository; 98 import sun.reflect.generics.scope.ClassScope; 99 import sun.security.util.SecurityConstants; 100 import sun.reflect.annotation.*; 101 import sun.reflect.misc.ReflectUtil; 102 103 /** 104 * Instances of the class {@code Class} represent classes and 105 * interfaces in a running Java application. An enum class and a record 106 * class are kinds of class; an annotation interface is a kind of 107 * interface. Every array also belongs to a class that is reflected as 108 * a {@code Class} object that is shared by all arrays with the same 109 * element type and number of dimensions. The primitive Java types 110 * ({@code boolean}, {@code byte}, {@code char}, {@code short}, {@code 111 * int}, {@code long}, {@code float}, and {@code double}), and the 112 * keyword {@code void} are also represented as {@code Class} objects. 113 * 114 * <p> {@code Class} has no public constructor. Instead a {@code Class} 115 * object is constructed automatically by the Java Virtual Machine when 116 * a class is derived from the bytes of a {@code class} file through 117 * the invocation of one of the following methods: 118 * <ul> 119 * <li> {@link ClassLoader#defineClass(String, byte[], int, int) ClassLoader::defineClass} 120 * <li> {@link java.lang.invoke.MethodHandles.Lookup#defineClass(byte[]) 121 * java.lang.invoke.MethodHandles.Lookup::defineClass} 122 * <li> {@link java.lang.invoke.MethodHandles.Lookup#defineHiddenClass(byte[], boolean, MethodHandles.Lookup.ClassOption...) 123 * java.lang.invoke.MethodHandles.Lookup::defineHiddenClass} 124 * </ul> 125 * 126 * <p> The methods of class {@code Class} expose many characteristics of a 127 * class or interface. Most characteristics are derived from the {@code class} 128 * file that the class loader passed to the Java Virtual Machine or 129 * from the {@code class} file passed to {@code Lookup::defineClass} 130 * or {@code Lookup::defineHiddenClass}. 131 * A few characteristics are determined by the class loading environment 132 * at run time, such as the module returned by {@link #getModule() getModule()}. 133 * 134 * <p> The following example uses a {@code Class} object to print the 135 * class name of an object: 136 * 137 * {@snippet lang="java" : 138 * void printClassName(Object obj) { 139 * System.out.println("The class of " + obj + 140 * " is " + obj.getClass().getName()); 141 * }} 142 * 143 * It is also possible to get the {@code Class} object for a named 144 * class or interface (or for {@code void}) using a <dfn>class literal</dfn> 145 * (JLS {@jls 15.8.2}). 146 * For example: 147 * 148 * {@snippet lang="java" : 149 * System.out.println("The name of class Foo is: " + Foo.class.getName()); // @highlight substring="Foo.class" 150 * } 151 * 152 * <p> Some methods of class {@code Class} expose whether the declaration of 153 * a class or interface in Java source code was <em>enclosed</em> within 154 * another declaration. Other methods describe how a class or interface 155 * is situated in a <dfn>{@index "nest"}</dfn>. A nest is a set of 156 * classes and interfaces, in the same run-time package, that 157 * allow mutual access to their {@code private} members. 158 * The classes and interfaces are known as <dfn>{@index "nestmates"}</dfn> 159 * (JVMS {@jvms 4.7.29}). 160 * One nestmate acts as the 161 * <dfn>nest host</dfn> (JVMS {@jvms 4.7.28}), and enumerates the other nestmates which 162 * belong to the nest; each of them in turn records it as the nest host. 163 * The classes and interfaces which belong to a nest, including its host, are 164 * determined when 165 * {@code class} files are generated, for example, a Java compiler 166 * will typically record a top-level class as the host of a nest where the 167 * other members are the classes and interfaces whose declarations are 168 * enclosed within the top-level class declaration. 169 * 170 * <h2><a id=hiddenClasses>Hidden Classes</a></h2> 171 * A class or interface created by the invocation of 172 * {@link java.lang.invoke.MethodHandles.Lookup#defineHiddenClass(byte[], boolean, MethodHandles.Lookup.ClassOption...) 173 * Lookup::defineHiddenClass} is a {@linkplain Class#isHidden() <dfn>hidden</dfn>} 174 * class or interface. 175 * All kinds of class, including enum classes and record classes, may be 176 * hidden classes; all kinds of interface, including annotation interfaces, 177 * may be hidden interfaces. 178 * 179 * The {@linkplain #getName() name of a hidden class or interface} is 180 * not a {@linkplain ClassLoader##binary-name binary name}, 181 * which means the following: 182 * <ul> 183 * <li>A hidden class or interface cannot be referenced by the constant pools 184 * of other classes and interfaces. 185 * <li>A hidden class or interface cannot be described in 186 * {@linkplain java.lang.constant.ConstantDesc <em>nominal form</em>} by 187 * {@link #describeConstable() Class::describeConstable}, 188 * {@link ClassDesc#of(String) ClassDesc::of}, or 189 * {@link ClassDesc#ofDescriptor(String) ClassDesc::ofDescriptor}. 190 * <li>A hidden class or interface cannot be discovered by {@link #forName Class::forName} 191 * or {@link ClassLoader#loadClass(String, boolean) ClassLoader::loadClass}. 192 * </ul> 193 * 194 * A hidden class or interface is never an array class, but may be 195 * the element type of an array. In all other respects, the fact that 196 * a class or interface is hidden has no bearing on the characteristics 197 * exposed by the methods of class {@code Class}. 198 * 199 * <h2><a id=implicitClasses>Implicitly Declared Classes</a></h2> 200 * 201 * Conventionally, a Java compiler, starting from a source file for an 202 * implicitly declared class, say {@code HelloWorld.java}, creates a 203 * similarly-named {@code class} file, {@code HelloWorld.class}, where 204 * the class stored in that {@code class} file is named {@code 205 * "HelloWorld"}, matching the base names of the source and {@code 206 * class} files. 207 * 208 * For the {@code Class} object of an implicitly declared class {@code 209 * HelloWorld}, the methods to get the {@linkplain #getName name} and 210 * {@linkplain #getTypeName type name} return results 211 * equal to {@code "HelloWorld"}. The {@linkplain #getSimpleName 212 * simple name} of such an implicitly declared class is {@code "HelloWorld"} and 213 * the {@linkplain #getCanonicalName canonical name} is {@code "HelloWorld"}. 214 * 215 * @param <T> the type of the class modeled by this {@code Class} 216 * object. For example, the type of {@code String.class} is {@code 217 * Class<String>}. Use {@code Class<?>} if the class being modeled is 218 * unknown. 219 * 220 * @see java.lang.ClassLoader#defineClass(byte[], int, int) 221 * @since 1.0 222 */ 223 public final class Class<T> implements java.io.Serializable, 224 GenericDeclaration, 225 Type, 226 AnnotatedElement, 227 TypeDescriptor.OfField<Class<?>>, 228 Constable { 229 private static final int ANNOTATION = 0x00002000; 230 private static final int ENUM = 0x00004000; 231 private static final int SYNTHETIC = 0x00001000; 232 233 private static native void registerNatives(); 234 static { 235 registerNatives(); 236 } 237 238 /* 239 * Private constructor. Only the Java Virtual Machine creates Class objects. 240 * This constructor is not used and prevents the default constructor being 241 * generated. 242 */ 243 private Class(ClassLoader loader, Class<?> arrayComponentType) { 244 // Initialize final field for classLoader. The initialization value of non-null 245 // prevents future JIT optimizations from assuming this final field is null. 246 classLoader = loader; 247 componentType = arrayComponentType; 248 } 249 250 /** 251 * Converts the object to a string. The string representation is the 252 * string "class" or "interface", followed by a space, and then by the 253 * name of the class in the format returned by {@code getName}. 254 * If this {@code Class} object represents a primitive type, 255 * this method returns the name of the primitive type. If 256 * this {@code Class} object represents void this method returns 257 * "void". If this {@code Class} object represents an array type, 258 * this method returns "class " followed by {@code getName}. 259 * 260 * @return a string representation of this {@code Class} object. 261 */ 262 public String toString() { 263 String kind = isInterface() ? "interface " : isPrimitive() ? "" : "class "; 264 return kind.concat(getName()); 265 } 266 267 /** 268 * Returns a string describing this {@code Class}, including 269 * information about modifiers, {@link #isSealed() sealed}/{@code 270 * non-sealed} status, and type parameters. 271 * 272 * The string is formatted as a list of type modifiers, if any, 273 * followed by the kind of type (empty string for primitive types 274 * and {@code class}, {@code enum}, {@code interface}, 275 * {@code @interface}, or {@code record} as appropriate), followed 276 * by the type's name, followed by an angle-bracketed 277 * comma-separated list of the type's type parameters, if any, 278 * including informative bounds on the type parameters, if any. 279 * 280 * A space is used to separate modifiers from one another and to 281 * separate any modifiers from the kind of type. The modifiers 282 * occur in canonical order. If there are no type parameters, the 283 * type parameter list is elided. 284 * 285 * For an array type, the string starts with the type name, 286 * followed by an angle-bracketed comma-separated list of the 287 * type's type parameters, if any, followed by a sequence of 288 * {@code []} characters, one set of brackets per dimension of 289 * the array. 290 * 291 * <p>Note that since information about the runtime representation 292 * of a type is being generated, modifiers not present on the 293 * originating source code or illegal on the originating source 294 * code may be present. 295 * 296 * @return a string describing this {@code Class}, including 297 * information about modifiers and type parameters 298 * 299 * @since 1.8 300 */ 301 public String toGenericString() { 302 if (isPrimitive()) { 303 return toString(); 304 } else { 305 StringBuilder sb = new StringBuilder(); 306 Class<?> component = this; 307 int arrayDepth = 0; 308 309 if (isArray()) { 310 do { 311 arrayDepth++; 312 component = component.getComponentType(); 313 } while (component.isArray()); 314 sb.append(component.getName()); 315 } else { 316 // Class modifiers are a superset of interface modifiers 317 int modifiers = getModifiers() & Modifier.classModifiers(); 318 // Modifier.toString() below mis-interprets SYNCHRONIZED, STRICT, and VOLATILE bits 319 modifiers &= ~(Modifier.SYNCHRONIZED | Modifier.STRICT | Modifier.VOLATILE); 320 if (modifiers != 0) { 321 sb.append(Modifier.toString(modifiers)); 322 sb.append(' '); 323 } 324 325 // A class cannot be strictfp and sealed/non-sealed so 326 // it is sufficient to check for sealed-ness after all 327 // modifiers are printed. 328 addSealingInfo(modifiers, sb); 329 330 if (isAnnotation()) { 331 sb.append('@'); 332 } 333 if (isValue()) { 334 sb.append("value "); 335 } 336 if (isInterface()) { // Note: all annotation interfaces are interfaces 337 sb.append("interface"); 338 } else { 339 if (isEnum()) 340 sb.append("enum"); 341 else if (isRecord()) 342 sb.append("record"); 343 else 344 sb.append("class"); 345 } 346 sb.append(' '); 347 sb.append(getName()); 348 } 349 350 TypeVariable<?>[] typeparms = component.getTypeParameters(); 351 if (typeparms.length > 0) { 352 sb.append(Arrays.stream(typeparms) 353 .map(Class::typeVarBounds) 354 .collect(Collectors.joining(",", "<", ">"))); 355 } 356 357 if (arrayDepth > 0) sb.append("[]".repeat(arrayDepth)); 358 359 return sb.toString(); 360 } 361 } 362 363 private void addSealingInfo(int modifiers, StringBuilder sb) { 364 // A class can be final XOR sealed XOR non-sealed. 365 if (Modifier.isFinal(modifiers)) { 366 return; // no-op 367 } else { 368 if (isSealed()) { 369 sb.append("sealed "); 370 return; 371 } else { 372 // Check for sealed ancestor, which implies this class 373 // is non-sealed. 374 if (hasSealedAncestor(this)) { 375 sb.append("non-sealed "); 376 } 377 } 378 } 379 } 380 381 private boolean hasSealedAncestor(Class<?> clazz) { 382 // From JLS 8.1.1.2: 383 // "It is a compile-time error if a class has a sealed direct 384 // superclass or a sealed direct superinterface, and is not 385 // declared final, sealed, or non-sealed either explicitly or 386 // implicitly. 387 // Thus, an effect of the sealed keyword is to force all 388 // direct subclasses to explicitly declare whether they are 389 // final, sealed, or non-sealed. This avoids accidentally 390 // exposing a sealed class hierarchy to unwanted subclassing." 391 392 // Therefore, will just check direct superclass and 393 // superinterfaces. 394 var superclass = clazz.getSuperclass(); 395 if (superclass != null && superclass.isSealed()) { 396 return true; 397 } 398 for (var superinterface : clazz.getInterfaces()) { 399 if (superinterface.isSealed()) { 400 return true; 401 } 402 } 403 return false; 404 } 405 406 static String typeVarBounds(TypeVariable<?> typeVar) { 407 Type[] bounds = typeVar.getBounds(); 408 if (bounds.length == 1 && bounds[0].equals(Object.class)) { 409 return typeVar.getName(); 410 } else { 411 return typeVar.getName() + " extends " + 412 Arrays.stream(bounds) 413 .map(Type::getTypeName) 414 .collect(Collectors.joining(" & ")); 415 } 416 } 417 418 /** 419 * Returns the {@code Class} object associated with the class or 420 * interface with the given string name. Invoking this method is 421 * equivalent to: 422 * 423 * {@snippet lang="java" : 424 * Class.forName(className, true, currentLoader) 425 * } 426 * 427 * where {@code currentLoader} denotes the defining class loader of 428 * the current class. 429 * 430 * <p> For example, the following code fragment returns the 431 * runtime {@code Class} object for the class named 432 * {@code java.lang.Thread}: 433 * 434 * {@snippet lang="java" : 435 * Class<?> t = Class.forName("java.lang.Thread"); 436 * } 437 * <p> 438 * A call to {@code forName("X")} causes the class named 439 * {@code X} to be initialized. 440 * 441 * <p> 442 * In cases where this method is called from a context where there is no 443 * caller frame on the stack (e.g. when called directly from a JNI 444 * attached thread), the system class loader is used. 445 * 446 * @param className the {@linkplain ClassLoader##binary-name binary name} 447 * of the class or the string representing an array type 448 * @return the {@code Class} object for the class with the 449 * specified name. 450 * @throws LinkageError if the linkage fails 451 * @throws ExceptionInInitializerError if the initialization provoked 452 * by this method fails 453 * @throws ClassNotFoundException if the class cannot be located 454 * 455 * @jls 12.2 Loading of Classes and Interfaces 456 * @jls 12.3 Linking of Classes and Interfaces 457 * @jls 12.4 Initialization of Classes and Interfaces 458 */ 459 @CallerSensitive 460 public static Class<?> forName(String className) 461 throws ClassNotFoundException { 462 Class<?> caller = Reflection.getCallerClass(); 463 return forName(className, caller); 464 } 465 466 // Caller-sensitive adapter method for reflective invocation 467 @CallerSensitiveAdapter 468 private static Class<?> forName(String className, Class<?> caller) 469 throws ClassNotFoundException { 470 ClassLoader loader = (caller == null) ? ClassLoader.getSystemClassLoader() 471 : ClassLoader.getClassLoader(caller); 472 return forName0(className, true, loader, caller); 473 } 474 475 /** 476 * Returns the {@code Class} object associated with the class or 477 * interface with the given string name, using the given class loader. 478 * Given the {@linkplain ClassLoader##binary-name binary name} for a class or interface, 479 * this method attempts to locate and load the class or interface. The specified 480 * class loader is used to load the class or interface. If the parameter 481 * {@code loader} is {@code null}, the class is loaded through the bootstrap 482 * class loader. The class is initialized only if the 483 * {@code initialize} parameter is {@code true} and if it has 484 * not been initialized earlier. 485 * 486 * <p> This method cannot be used to obtain any of the {@code Class} objects 487 * representing primitive types or void, hidden classes or interfaces, 488 * or array classes whose element type is a hidden class or interface. 489 * If {@code name} denotes a primitive type or void, for example {@code I}, 490 * an attempt will be made to locate a user-defined class in the unnamed package 491 * whose name is {@code I} instead. 492 * To obtain a {@code Class} object for a named primitive type 493 * such as {@code int} or {@code long} use {@link 494 * #forPrimitiveName(String)}. 495 * 496 * <p> To obtain the {@code Class} object associated with an array class, 497 * the name consists of one or more {@code '['} representing the depth 498 * of the array nesting, followed by the element type as encoded in 499 * {@linkplain ##nameFormat the table} specified in {@code Class.getName()}. 500 * 501 * <p> Examples: 502 * {@snippet lang="java" : 503 * Class<?> threadClass = Class.forName("java.lang.Thread", false, currentLoader); 504 * Class<?> stringArrayClass = Class.forName("[Ljava.lang.String;", false, currentLoader); 505 * Class<?> intArrayClass = Class.forName("[[[I", false, currentLoader); // Class of int[][][] 506 * Class<?> nestedClass = Class.forName("java.lang.Character$UnicodeBlock", false, currentLoader); 507 * Class<?> fooClass = Class.forName("Foo", true, currentLoader); 508 * } 509 * 510 * <p> A call to {@code getName()} on the {@code Class} object returned 511 * from {@code forName(}<i>N</i>{@code )} returns <i>N</i>. 512 * 513 * <p> A call to {@code forName("[L}<i>N</i>{@code ;")} causes the element type 514 * named <i>N</i> to be loaded but not initialized regardless of the value 515 * of the {@code initialize} parameter. 516 * 517 * @apiNote 518 * This method throws errors related to loading, linking or initializing 519 * as specified in Sections {@jls 12.2}, {@jls 12.3}, and {@jls 12.4} of 520 * <cite>The Java Language Specification</cite>. 521 * In addition, this method does not check whether the requested class 522 * is accessible to its caller. 523 * 524 * @param name the {@linkplain ClassLoader##binary-name binary name} 525 * of the class or the string representing an array class 526 * 527 * @param initialize if {@code true} the class will be initialized 528 * (which implies linking). See Section {@jls 529 * 12.4} of <cite>The Java Language 530 * Specification</cite>. 531 * @param loader class loader from which the class must be loaded 532 * @return class object representing the desired class 533 * 534 * @throws LinkageError if the linkage fails 535 * @throws ExceptionInInitializerError if the initialization provoked 536 * by this method fails 537 * @throws ClassNotFoundException if the class cannot be located by 538 * the specified class loader 539 * @throws SecurityException 540 * if a security manager is present, and the {@code loader} is 541 * {@code null}, and the caller's class loader is not 542 * {@code null}, and the caller does not have the 543 * {@link RuntimePermission}{@code ("getClassLoader")} 544 * 545 * @see java.lang.Class#forName(String) 546 * @see java.lang.ClassLoader 547 * 548 * @jls 12.2 Loading of Classes and Interfaces 549 * @jls 12.3 Linking of Classes and Interfaces 550 * @jls 12.4 Initialization of Classes and Interfaces 551 * @jls 13.1 The Form of a Binary 552 * @since 1.2 553 */ 554 @CallerSensitive 555 public static Class<?> forName(String name, boolean initialize, 556 ClassLoader loader) 557 throws ClassNotFoundException 558 { 559 Class<?> caller = null; 560 @SuppressWarnings("removal") 561 SecurityManager sm = System.getSecurityManager(); 562 if (sm != null) { 563 // Reflective call to get caller class is only needed if a security manager 564 // is present. Avoid the overhead of making this call otherwise. 565 caller = Reflection.getCallerClass(); 566 } 567 return forName(name, initialize, loader, caller); 568 } 569 570 // Caller-sensitive adapter method for reflective invocation 571 @CallerSensitiveAdapter 572 private static Class<?> forName(String name, boolean initialize, ClassLoader loader, Class<?> caller) 573 throws ClassNotFoundException 574 { 575 @SuppressWarnings("removal") 576 SecurityManager sm = System.getSecurityManager(); 577 if (sm != null) { 578 // Reflective call to get caller class is only needed if a security manager 579 // is present. Avoid the overhead of making this call otherwise. 580 if (loader == null) { 581 ClassLoader ccl = ClassLoader.getClassLoader(caller); 582 if (ccl != null) { 583 sm.checkPermission( 584 SecurityConstants.GET_CLASSLOADER_PERMISSION); 585 } 586 } 587 } 588 return forName0(name, initialize, loader, caller); 589 } 590 591 /** Called after security check for system loader access checks have been made. */ 592 private static native Class<?> forName0(String name, boolean initialize, 593 ClassLoader loader, 594 Class<?> caller) 595 throws ClassNotFoundException; 596 597 598 /** 599 * Returns the {@code Class} with the given {@linkplain ClassLoader##binary-name 600 * binary name} in the given module. 601 * 602 * <p> This method attempts to locate and load the class or interface. 603 * It does not link the class, and does not run the class initializer. 604 * If the class is not found, this method returns {@code null}. </p> 605 * 606 * <p> If the class loader of the given module defines other modules and 607 * the given name is a class defined in a different module, this method 608 * returns {@code null} after the class is loaded. </p> 609 * 610 * <p> This method does not check whether the requested class is 611 * accessible to its caller. </p> 612 * 613 * @apiNote 614 * This method does not support loading of array types, unlike 615 * {@link #forName(String, boolean, ClassLoader)}. The class name must be 616 * a binary name. This method returns {@code null} on failure rather than 617 * throwing a {@link ClassNotFoundException}, as is done by 618 * the {@link #forName(String, boolean, ClassLoader)} method. 619 * The security check is a stack-based permission check if the caller 620 * loads a class in another module. 621 * 622 * @param module A module 623 * @param name The {@linkplain ClassLoader##binary-name binary name} 624 * of the class 625 * @return {@code Class} object of the given name defined in the given module; 626 * {@code null} if not found. 627 * 628 * @throws NullPointerException if the given module or name is {@code null} 629 * 630 * @throws LinkageError if the linkage fails 631 * 632 * @throws SecurityException 633 * <ul> 634 * <li> if the caller is not the specified module and 635 * {@code RuntimePermission("getClassLoader")} permission is denied; or</li> 636 * <li> access to the module content is denied. For example, 637 * permission check will be performed when a class loader calls 638 * {@link ModuleReader#open(String)} to read the bytes of a class file 639 * in a module.</li> 640 * </ul> 641 * 642 * @jls 12.2 Loading of Classes and Interfaces 643 * @jls 12.3 Linking of Classes and Interfaces 644 * @since 9 645 */ 646 @SuppressWarnings("removal") 647 @CallerSensitive 648 public static Class<?> forName(Module module, String name) { 649 Class<?> caller = null; 650 SecurityManager sm = System.getSecurityManager(); 651 if (sm != null) { 652 caller = Reflection.getCallerClass(); 653 } 654 return forName(module, name, caller); 655 } 656 657 // Caller-sensitive adapter method for reflective invocation 658 @SuppressWarnings("removal") 659 @CallerSensitiveAdapter 660 private static Class<?> forName(Module module, String name, Class<?> caller) { 661 Objects.requireNonNull(module); 662 Objects.requireNonNull(name); 663 664 ClassLoader cl; 665 SecurityManager sm = System.getSecurityManager(); 666 if (sm != null) { 667 if (caller != null && caller.getModule() != module) { 668 // if caller is null, Class.forName is the last java frame on the stack. 669 // java.base has all permissions 670 sm.checkPermission(SecurityConstants.GET_CLASSLOADER_PERMISSION); 671 } 672 PrivilegedAction<ClassLoader> pa = module::getClassLoader; 673 cl = AccessController.doPrivileged(pa); 674 } else { 675 cl = module.getClassLoader(); 676 } 677 678 if (cl != null) { 679 return cl.loadClass(module, name); 680 } else { 681 return BootLoader.loadClass(module, name); 682 } 683 } 684 685 /** 686 * {@return {@code true} if this {@code Class} object represents an identity 687 * class or interface; otherwise {@code false}} 688 * 689 * If this {@code Class} object represents an array type, then this method 690 * returns {@code true}. 691 * If this {@code Class} object represents a primitive type, or {@code void}, 692 * then this method returns {@code false}. 693 * 694 * @since Valhalla 695 */ 696 @PreviewFeature(feature = PreviewFeature.Feature.VALUE_OBJECTS, reflective=true) 697 public native boolean isIdentity(); 698 699 /** 700 * {@return {@code true} if this {@code Class} object represents a value 701 * class; otherwise {@code false}} 702 * 703 * If this {@code Class} object represents an array type, an interface, 704 * a primitive type, or {@code void}, then this method returns {@code false}. 705 * 706 * @since Valhalla 707 */ 708 @PreviewFeature(feature = PreviewFeature.Feature.VALUE_OBJECTS, reflective=true) 709 public boolean isValue() { 710 if (!PreviewFeatures.isEnabled()) { 711 return false; 712 } 713 if (isPrimitive() || isArray() || isInterface()) 714 return false; 715 return ((getModifiers() & Modifier.IDENTITY) == 0); 716 } 717 718 /** 719 * {@return the {@code Class} object associated with the 720 * {@linkplain #isPrimitive() primitive type} of the given name} 721 * If the argument is not the name of a primitive type, {@code 722 * null} is returned. 723 * 724 * @param primitiveName the name of the primitive type to find 725 * 726 * @throws NullPointerException if the argument is {@code null} 727 * 728 * @jls 4.2 Primitive Types and Values 729 * @jls 15.8.2 Class Literals 730 * @since 22 731 */ 732 public static Class<?> forPrimitiveName(String primitiveName) { 733 return switch(primitiveName) { 734 // Integral types 735 case "int" -> int.class; 736 case "long" -> long.class; 737 case "short" -> short.class; 738 case "char" -> char.class; 739 case "byte" -> byte.class; 740 741 // Floating-point types 742 case "float" -> float.class; 743 case "double" -> double.class; 744 745 // Other types 746 case "boolean" -> boolean.class; 747 case "void" -> void.class; 748 749 default -> null; 750 }; 751 } 752 753 /** 754 * Creates a new instance of the class represented by this {@code Class} 755 * object. The class is instantiated as if by a {@code new} 756 * expression with an empty argument list. The class is initialized if it 757 * has not already been initialized. 758 * 759 * @deprecated This method propagates any exception thrown by the 760 * nullary constructor, including a checked exception. Use of 761 * this method effectively bypasses the compile-time exception 762 * checking that would otherwise be performed by the compiler. 763 * The {@link 764 * java.lang.reflect.Constructor#newInstance(java.lang.Object...) 765 * Constructor.newInstance} method avoids this problem by wrapping 766 * any exception thrown by the constructor in a (checked) {@link 767 * java.lang.reflect.InvocationTargetException}. 768 * 769 * <p>The call 770 * 771 * {@snippet lang="java" : 772 * clazz.newInstance() 773 * } 774 * 775 * can be replaced by 776 * 777 * {@snippet lang="java" : 778 * clazz.getDeclaredConstructor().newInstance() 779 * } 780 * 781 * The latter sequence of calls is inferred to be able to throw 782 * the additional exception types {@link 783 * InvocationTargetException} and {@link 784 * NoSuchMethodException}. Both of these exception types are 785 * subclasses of {@link ReflectiveOperationException}. 786 * 787 * @return a newly allocated instance of the class represented by this 788 * object. 789 * @throws IllegalAccessException if the class or its nullary 790 * constructor is not accessible. 791 * @throws InstantiationException 792 * if this {@code Class} represents an abstract class, 793 * an interface, an array class, a primitive type, or void; 794 * or if the class has no nullary constructor; 795 * or if the instantiation fails for some other reason. 796 * @throws ExceptionInInitializerError if the initialization 797 * provoked by this method fails. 798 * @throws SecurityException 799 * If a security manager, <i>s</i>, is present and 800 * the caller's class loader is not the same as or an 801 * ancestor of the class loader for the current class and 802 * invocation of {@link SecurityManager#checkPackageAccess 803 * s.checkPackageAccess()} denies access to the package 804 * of this class. 805 */ 806 @SuppressWarnings("removal") 807 @CallerSensitive 808 @Deprecated(since="9") 809 public T newInstance() 810 throws InstantiationException, IllegalAccessException 811 { 812 SecurityManager sm = System.getSecurityManager(); 813 if (sm != null) { 814 checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), false); 815 } 816 817 // Constructor lookup 818 Constructor<T> tmpConstructor = cachedConstructor; 819 if (tmpConstructor == null) { 820 if (this == Class.class) { 821 throw new IllegalAccessException( 822 "Can not call newInstance() on the Class for java.lang.Class" 823 ); 824 } 825 try { 826 Class<?>[] empty = {}; 827 final Constructor<T> c = getReflectionFactory().copyConstructor( 828 getConstructor0(empty, Member.DECLARED)); 829 // Disable accessibility checks on the constructor 830 // access check is done with the true caller 831 java.security.AccessController.doPrivileged( 832 new java.security.PrivilegedAction<>() { 833 public Void run() { 834 c.setAccessible(true); 835 return null; 836 } 837 }); 838 cachedConstructor = tmpConstructor = c; 839 } catch (NoSuchMethodException e) { 840 throw (InstantiationException) 841 new InstantiationException(getName()).initCause(e); 842 } 843 } 844 845 try { 846 Class<?> caller = Reflection.getCallerClass(); 847 return getReflectionFactory().newInstance(tmpConstructor, null, caller); 848 } catch (InvocationTargetException e) { 849 Unsafe.getUnsafe().throwException(e.getTargetException()); 850 // Not reached 851 return null; 852 } 853 } 854 855 private transient volatile Constructor<T> cachedConstructor; 856 857 /** 858 * Determines if the specified {@code Object} is assignment-compatible 859 * with the object represented by this {@code Class}. This method is 860 * the dynamic equivalent of the Java language {@code instanceof} 861 * operator. The method returns {@code true} if the specified 862 * {@code Object} argument is non-null and can be cast to the 863 * reference type represented by this {@code Class} object without 864 * raising a {@code ClassCastException.} It returns {@code false} 865 * otherwise. 866 * 867 * <p> Specifically, if this {@code Class} object represents a 868 * declared class, this method returns {@code true} if the specified 869 * {@code Object} argument is an instance of the represented class (or 870 * of any of its subclasses); it returns {@code false} otherwise. If 871 * this {@code Class} object represents an array class, this method 872 * returns {@code true} if the specified {@code Object} argument 873 * can be converted to an object of the array class by an identity 874 * conversion or by a widening reference conversion; it returns 875 * {@code false} otherwise. If this {@code Class} object 876 * represents an interface, this method returns {@code true} if the 877 * class or any superclass of the specified {@code Object} argument 878 * implements this interface; it returns {@code false} otherwise. If 879 * this {@code Class} object represents a primitive type, this method 880 * returns {@code false}. 881 * 882 * @param obj the object to check 883 * @return true if {@code obj} is an instance of this class 884 * 885 * @since 1.1 886 */ 887 @IntrinsicCandidate 888 public native boolean isInstance(Object obj); 889 890 891 /** 892 * Determines if the class or interface represented by this 893 * {@code Class} object is either the same as, or is a superclass or 894 * superinterface of, the class or interface represented by the specified 895 * {@code Class} parameter. It returns {@code true} if so; 896 * otherwise it returns {@code false}. If this {@code Class} 897 * object represents a primitive type, this method returns 898 * {@code true} if the specified {@code Class} parameter is 899 * exactly this {@code Class} object; otherwise it returns 900 * {@code false}. 901 * 902 * <p> Specifically, this method tests whether the type represented by the 903 * specified {@code Class} parameter can be converted to the type 904 * represented by this {@code Class} object via an identity conversion 905 * or via a widening reference conversion. See <cite>The Java Language 906 * Specification</cite>, sections {@jls 5.1.1} and {@jls 5.1.4}, 907 * for details. 908 * 909 * @param cls the {@code Class} object to be checked 910 * @return the {@code boolean} value indicating whether objects of the 911 * type {@code cls} can be assigned to objects of this class 912 * @throws NullPointerException if the specified Class parameter is 913 * null. 914 * @since 1.1 915 */ 916 @IntrinsicCandidate 917 public native boolean isAssignableFrom(Class<?> cls); 918 919 920 /** 921 * Determines if this {@code Class} object represents an 922 * interface type. 923 * 924 * @return {@code true} if this {@code Class} object represents an interface; 925 * {@code false} otherwise. 926 */ 927 @IntrinsicCandidate 928 public native boolean isInterface(); 929 930 931 /** 932 * Determines if this {@code Class} object represents an array class. 933 * 934 * @return {@code true} if this {@code Class} object represents an array class; 935 * {@code false} otherwise. 936 * @since 1.1 937 */ 938 @IntrinsicCandidate 939 public native boolean isArray(); 940 941 942 /** 943 * Determines if this {@code Class} object represents a primitive 944 * type or void. 945 * 946 * <p> There are nine predefined {@code Class} objects to 947 * represent the eight primitive types and void. These are 948 * created by the Java Virtual Machine, and have the same 949 * {@linkplain #getName() names} as the primitive types that they 950 * represent, namely {@code boolean}, {@code byte}, {@code char}, 951 * {@code short}, {@code int}, {@code long}, {@code float}, and 952 * {@code double}. 953 * 954 * <p>No other class objects are considered primitive. 955 * 956 * @apiNote 957 * A {@code Class} object represented by a primitive type can be 958 * accessed via the {@code TYPE} public static final variables 959 * defined in the primitive wrapper classes such as {@link 960 * java.lang.Integer#TYPE Integer.TYPE}. In the Java programming 961 * language, the objects may be referred to by a class literal 962 * expression such as {@code int.class}. The {@code Class} object 963 * for void can be expressed as {@code void.class} or {@link 964 * java.lang.Void#TYPE Void.TYPE}. 965 * 966 * @return true if and only if this class represents a primitive type 967 * 968 * @see java.lang.Boolean#TYPE 969 * @see java.lang.Character#TYPE 970 * @see java.lang.Byte#TYPE 971 * @see java.lang.Short#TYPE 972 * @see java.lang.Integer#TYPE 973 * @see java.lang.Long#TYPE 974 * @see java.lang.Float#TYPE 975 * @see java.lang.Double#TYPE 976 * @see java.lang.Void#TYPE 977 * @since 1.1 978 * @jls 15.8.2 Class Literals 979 */ 980 @IntrinsicCandidate 981 public native boolean isPrimitive(); 982 983 /** 984 * Returns true if this {@code Class} object represents an annotation 985 * interface. Note that if this method returns true, {@link #isInterface()} 986 * would also return true, as all annotation interfaces are also interfaces. 987 * 988 * @return {@code true} if this {@code Class} object represents an annotation 989 * interface; {@code false} otherwise 990 * @since 1.5 991 */ 992 public boolean isAnnotation() { 993 return (getModifiers() & ANNOTATION) != 0; 994 } 995 996 /** 997 *{@return {@code true} if and only if this class has the synthetic modifier 998 * bit set} 999 * 1000 * @jls 13.1 The Form of a Binary 1001 * @jvms 4.1 The {@code ClassFile} Structure 1002 * @see <a 1003 * href="{@docRoot}/java.base/java/lang/reflect/package-summary.html#LanguageJvmModel">Java 1004 * programming language and JVM modeling in core reflection</a> 1005 * @since 1.5 1006 */ 1007 public boolean isSynthetic() { 1008 return (getModifiers() & SYNTHETIC) != 0; 1009 } 1010 1011 /** 1012 * Returns the name of the entity (class, interface, array class, 1013 * primitive type, or void) represented by this {@code Class} object. 1014 * 1015 * <p> If this {@code Class} object represents a class or interface, 1016 * not an array class, then: 1017 * <ul> 1018 * <li> If the class or interface is not {@linkplain #isHidden() hidden}, 1019 * then the {@linkplain ClassLoader##binary-name binary name} 1020 * of the class or interface is returned. 1021 * <li> If the class or interface is hidden, then the result is a string 1022 * of the form: {@code N + '/' + <suffix>} 1023 * where {@code N} is the {@linkplain ClassLoader##binary-name binary name} 1024 * indicated by the {@code class} file passed to 1025 * {@link java.lang.invoke.MethodHandles.Lookup#defineHiddenClass(byte[], boolean, MethodHandles.Lookup.ClassOption...) 1026 * Lookup::defineHiddenClass}, and {@code <suffix>} is an unqualified name. 1027 * </ul> 1028 * 1029 * <p> If this {@code Class} object represents an array class, then 1030 * the result is a string consisting of one or more '{@code [}' characters 1031 * representing the depth of the array nesting, followed by the element 1032 * type as encoded using the following table: 1033 * 1034 * <blockquote><table class="striped" id="nameFormat"> 1035 * <caption style="display:none">Element types and encodings</caption> 1036 * <thead> 1037 * <tr><th scope="col"> Element Type <th scope="col"> Encoding 1038 * </thead> 1039 * <tbody style="text-align:left"> 1040 * <tr><th scope="row"> {@code boolean} <td style="text-align:center"> {@code Z} 1041 * <tr><th scope="row"> {@code byte} <td style="text-align:center"> {@code B} 1042 * <tr><th scope="row"> {@code char} <td style="text-align:center"> {@code C} 1043 * <tr><th scope="row"> class or interface with {@linkplain ClassLoader##binary-name binary name} <i>N</i> 1044 * <td style="text-align:center"> {@code L}<em>N</em>{@code ;} 1045 * <tr><th scope="row"> {@code double} <td style="text-align:center"> {@code D} 1046 * <tr><th scope="row"> {@code float} <td style="text-align:center"> {@code F} 1047 * <tr><th scope="row"> {@code int} <td style="text-align:center"> {@code I} 1048 * <tr><th scope="row"> {@code long} <td style="text-align:center"> {@code J} 1049 * <tr><th scope="row"> {@code short} <td style="text-align:center"> {@code S} 1050 * </tbody> 1051 * </table></blockquote> 1052 * 1053 * <p> If this {@code Class} object represents a primitive type or {@code void}, 1054 * then the result is a string with the same spelling as the Java language 1055 * keyword which corresponds to the primitive type or {@code void}. 1056 * 1057 * <p> Examples: 1058 * <blockquote><pre> 1059 * String.class.getName() 1060 * returns "java.lang.String" 1061 * Character.UnicodeBlock.class.getName() 1062 * returns "java.lang.Character$UnicodeBlock" 1063 * byte.class.getName() 1064 * returns "byte" 1065 * (new Object[3]).getClass().getName() 1066 * returns "[Ljava.lang.Object;" 1067 * (new int[3][4][5][6][7][8][9]).getClass().getName() 1068 * returns "[[[[[[[I" 1069 * </pre></blockquote> 1070 * 1071 * @apiNote 1072 * Distinct class objects can have the same name but different class loaders. 1073 * 1074 * @return the name of the class, interface, or other entity 1075 * represented by this {@code Class} object. 1076 * @jls 13.1 The Form of a Binary 1077 */ 1078 public String getName() { 1079 String name = this.name; 1080 return name != null ? name : initClassName(); 1081 } 1082 1083 // Cache the name to reduce the number of calls into the VM. 1084 // This field would be set by VM itself during initClassName call. 1085 private transient String name; 1086 private native String initClassName(); 1087 1088 /** 1089 * Returns the class loader for the class. Some implementations may use 1090 * null to represent the bootstrap class loader. This method will return 1091 * null in such implementations if this class was loaded by the bootstrap 1092 * class loader. 1093 * 1094 * <p>If this {@code Class} object 1095 * represents a primitive type or void, null is returned. 1096 * 1097 * @return the class loader that loaded the class or interface 1098 * represented by this {@code Class} object. 1099 * @throws SecurityException 1100 * if a security manager is present, and the caller's class loader 1101 * is not {@code null} and is not the same as or an ancestor of the 1102 * class loader for the class whose class loader is requested, 1103 * and the caller does not have the 1104 * {@link RuntimePermission}{@code ("getClassLoader")} 1105 * @see java.lang.ClassLoader 1106 * @see SecurityManager#checkPermission 1107 * @see java.lang.RuntimePermission 1108 */ 1109 @CallerSensitive 1110 @ForceInline // to ensure Reflection.getCallerClass optimization 1111 public ClassLoader getClassLoader() { 1112 ClassLoader cl = classLoader; 1113 if (cl == null) 1114 return null; 1115 @SuppressWarnings("removal") 1116 SecurityManager sm = System.getSecurityManager(); 1117 if (sm != null) { 1118 ClassLoader.checkClassLoaderPermission(cl, Reflection.getCallerClass()); 1119 } 1120 return cl; 1121 } 1122 1123 // Package-private to allow ClassLoader access 1124 ClassLoader getClassLoader0() { return classLoader; } 1125 1126 /** 1127 * Returns the module that this class or interface is a member of. 1128 * 1129 * If this class represents an array type then this method returns the 1130 * {@code Module} for the element type. If this class represents a 1131 * primitive type or void, then the {@code Module} object for the 1132 * {@code java.base} module is returned. 1133 * 1134 * If this class is in an unnamed module then the {@linkplain 1135 * ClassLoader#getUnnamedModule() unnamed} {@code Module} of the class 1136 * loader for this class is returned. 1137 * 1138 * @return the module that this class or interface is a member of 1139 * 1140 * @since 9 1141 */ 1142 public Module getModule() { 1143 return module; 1144 } 1145 1146 // set by VM 1147 @Stable 1148 private transient Module module; 1149 1150 // Initialized in JVM not by private constructor 1151 // This field is filtered from reflection access, i.e. getDeclaredField 1152 // will throw NoSuchFieldException 1153 private final ClassLoader classLoader; 1154 1155 private transient Object classData; // Set by VM 1156 private transient Object[] signers; // Read by VM, mutable 1157 1158 // package-private 1159 Object getClassData() { 1160 return classData; 1161 } 1162 1163 /** 1164 * Returns an array of {@code TypeVariable} objects that represent the 1165 * type variables declared by the generic declaration represented by this 1166 * {@code GenericDeclaration} object, in declaration order. Returns an 1167 * array of length 0 if the underlying generic declaration declares no type 1168 * variables. 1169 * 1170 * @return an array of {@code TypeVariable} objects that represent 1171 * the type variables declared by this generic declaration 1172 * @throws java.lang.reflect.GenericSignatureFormatError if the generic 1173 * signature of this generic declaration does not conform to 1174 * the format specified in section {@jvms 4.7.9} of 1175 * <cite>The Java Virtual Machine Specification</cite> 1176 * @since 1.5 1177 */ 1178 @SuppressWarnings("unchecked") 1179 public TypeVariable<Class<T>>[] getTypeParameters() { 1180 ClassRepository info = getGenericInfo(); 1181 if (info != null) 1182 return (TypeVariable<Class<T>>[])info.getTypeParameters(); 1183 else 1184 return (TypeVariable<Class<T>>[])new TypeVariable<?>[0]; 1185 } 1186 1187 1188 /** 1189 * Returns the {@code Class} representing the direct superclass of the 1190 * entity (class, interface, primitive type or void) represented by 1191 * this {@code Class}. If this {@code Class} represents either the 1192 * {@code Object} class, an interface, a primitive type, or void, then 1193 * null is returned. If this {@code Class} object represents an array class 1194 * then the {@code Class} object representing the {@code Object} class is 1195 * returned. 1196 * 1197 * @return the direct superclass of the class represented by this {@code Class} object 1198 */ 1199 @IntrinsicCandidate 1200 public native Class<? super T> getSuperclass(); 1201 1202 1203 /** 1204 * Returns the {@code Type} representing the direct superclass of 1205 * the entity (class, interface, primitive type or void) represented by 1206 * this {@code Class} object. 1207 * 1208 * <p>If the superclass is a parameterized type, the {@code Type} 1209 * object returned must accurately reflect the actual type 1210 * arguments used in the source code. The parameterized type 1211 * representing the superclass is created if it had not been 1212 * created before. See the declaration of {@link 1213 * java.lang.reflect.ParameterizedType ParameterizedType} for the 1214 * semantics of the creation process for parameterized types. If 1215 * this {@code Class} object represents either the {@code Object} 1216 * class, an interface, a primitive type, or void, then null is 1217 * returned. If this {@code Class} object represents an array class 1218 * then the {@code Class} object representing the {@code Object} class is 1219 * returned. 1220 * 1221 * @throws java.lang.reflect.GenericSignatureFormatError if the generic 1222 * class signature does not conform to the format specified in 1223 * section {@jvms 4.7.9} of <cite>The Java Virtual 1224 * Machine Specification</cite> 1225 * @throws TypeNotPresentException if the generic superclass 1226 * refers to a non-existent type declaration 1227 * @throws java.lang.reflect.MalformedParameterizedTypeException if the 1228 * generic superclass refers to a parameterized type that cannot be 1229 * instantiated for any reason 1230 * @return the direct superclass of the class represented by this {@code Class} object 1231 * @since 1.5 1232 */ 1233 public Type getGenericSuperclass() { 1234 ClassRepository info = getGenericInfo(); 1235 if (info == null) { 1236 return getSuperclass(); 1237 } 1238 1239 // Historical irregularity: 1240 // Generic signature marks interfaces with superclass = Object 1241 // but this API returns null for interfaces 1242 if (isInterface()) { 1243 return null; 1244 } 1245 1246 return info.getSuperclass(); 1247 } 1248 1249 /** 1250 * Gets the package of this class. 1251 * 1252 * <p>If this class represents an array type, a primitive type or void, 1253 * this method returns {@code null}. 1254 * 1255 * @return the package of this class. 1256 */ 1257 public Package getPackage() { 1258 if (isPrimitive() || isArray()) { 1259 return null; 1260 } 1261 ClassLoader cl = classLoader; 1262 return cl != null ? cl.definePackage(this) 1263 : BootLoader.definePackage(this); 1264 } 1265 1266 /** 1267 * Returns the fully qualified package name. 1268 * 1269 * <p> If this class is a top level class, then this method returns the fully 1270 * qualified name of the package that the class is a member of, or the 1271 * empty string if the class is in an unnamed package. 1272 * 1273 * <p> If this class is a member class, then this method is equivalent to 1274 * invoking {@code getPackageName()} on the {@linkplain #getEnclosingClass 1275 * enclosing class}. 1276 * 1277 * <p> If this class is a {@linkplain #isLocalClass local class} or an {@linkplain 1278 * #isAnonymousClass() anonymous class}, then this method is equivalent to 1279 * invoking {@code getPackageName()} on the {@linkplain #getDeclaringClass 1280 * declaring class} of the {@linkplain #getEnclosingMethod enclosing method} or 1281 * {@linkplain #getEnclosingConstructor enclosing constructor}. 1282 * 1283 * <p> If this class represents an array type then this method returns the 1284 * package name of the element type. If this class represents a primitive 1285 * type or void then the package name "{@code java.lang}" is returned. 1286 * 1287 * @return the fully qualified package name 1288 * 1289 * @since 9 1290 * @jls 6.7 Fully Qualified Names and Canonical Names 1291 */ 1292 public String getPackageName() { 1293 String pn = this.packageName; 1294 if (pn == null) { 1295 Class<?> c = isArray() ? elementType() : this; 1296 if (c.isPrimitive()) { 1297 pn = "java.lang"; 1298 } else { 1299 String cn = c.getName(); 1300 int dot = cn.lastIndexOf('.'); 1301 pn = (dot != -1) ? cn.substring(0, dot).intern() : ""; 1302 } 1303 this.packageName = pn; 1304 } 1305 return pn; 1306 } 1307 1308 // cached package name 1309 private transient String packageName; 1310 1311 /** 1312 * Returns the interfaces directly implemented by the class or interface 1313 * represented by this {@code Class} object. 1314 * 1315 * <p>If this {@code Class} object represents a class, the return value is an array 1316 * containing objects representing all interfaces directly implemented by 1317 * the class. The order of the interface objects in the array corresponds 1318 * to the order of the interface names in the {@code implements} clause of 1319 * the declaration of the class represented by this {@code Class} object. For example, 1320 * given the declaration: 1321 * <blockquote> 1322 * {@code class Shimmer implements FloorWax, DessertTopping { ... }} 1323 * </blockquote> 1324 * suppose the value of {@code s} is an instance of 1325 * {@code Shimmer}; the value of the expression: 1326 * <blockquote> 1327 * {@code s.getClass().getInterfaces()[0]} 1328 * </blockquote> 1329 * is the {@code Class} object that represents interface 1330 * {@code FloorWax}; and the value of: 1331 * <blockquote> 1332 * {@code s.getClass().getInterfaces()[1]} 1333 * </blockquote> 1334 * is the {@code Class} object that represents interface 1335 * {@code DessertTopping}. 1336 * 1337 * <p>If this {@code Class} object represents an interface, the array contains objects 1338 * representing all interfaces directly extended by the interface. The 1339 * order of the interface objects in the array corresponds to the order of 1340 * the interface names in the {@code extends} clause of the declaration of 1341 * the interface represented by this {@code Class} object. 1342 * 1343 * <p>If this {@code Class} object represents a class or interface that implements no 1344 * interfaces, the method returns an array of length 0. 1345 * 1346 * <p>If this {@code Class} object represents a primitive type or void, the method 1347 * returns an array of length 0. 1348 * 1349 * <p>If this {@code Class} object represents an array type, the 1350 * interfaces {@code Cloneable} and {@code java.io.Serializable} are 1351 * returned in that order. 1352 * 1353 * @return an array of interfaces directly implemented by this class 1354 */ 1355 public Class<?>[] getInterfaces() { 1356 // defensively copy before handing over to user code 1357 return getInterfaces(true); 1358 } 1359 1360 private Class<?>[] getInterfaces(boolean cloneArray) { 1361 ReflectionData<T> rd = reflectionData(); 1362 if (rd == null) { 1363 // no cloning required 1364 return getInterfaces0(); 1365 } else { 1366 Class<?>[] interfaces = rd.interfaces; 1367 if (interfaces == null) { 1368 interfaces = getInterfaces0(); 1369 rd.interfaces = interfaces; 1370 } 1371 // defensively copy if requested 1372 return cloneArray ? interfaces.clone() : interfaces; 1373 } 1374 } 1375 1376 private native Class<?>[] getInterfaces0(); 1377 1378 /** 1379 * Returns the {@code Type}s representing the interfaces 1380 * directly implemented by the class or interface represented by 1381 * this {@code Class} object. 1382 * 1383 * <p>If a superinterface is a parameterized type, the 1384 * {@code Type} object returned for it must accurately reflect 1385 * the actual type arguments used in the source code. The 1386 * parameterized type representing each superinterface is created 1387 * if it had not been created before. See the declaration of 1388 * {@link java.lang.reflect.ParameterizedType ParameterizedType} 1389 * for the semantics of the creation process for parameterized 1390 * types. 1391 * 1392 * <p>If this {@code Class} object represents a class, the return value is an array 1393 * containing objects representing all interfaces directly implemented by 1394 * the class. The order of the interface objects in the array corresponds 1395 * to the order of the interface names in the {@code implements} clause of 1396 * the declaration of the class represented by this {@code Class} object. 1397 * 1398 * <p>If this {@code Class} object represents an interface, the array contains objects 1399 * representing all interfaces directly extended by the interface. The 1400 * order of the interface objects in the array corresponds to the order of 1401 * the interface names in the {@code extends} clause of the declaration of 1402 * the interface represented by this {@code Class} object. 1403 * 1404 * <p>If this {@code Class} object represents a class or interface that implements no 1405 * interfaces, the method returns an array of length 0. 1406 * 1407 * <p>If this {@code Class} object represents a primitive type or void, the method 1408 * returns an array of length 0. 1409 * 1410 * <p>If this {@code Class} object represents an array type, the 1411 * interfaces {@code Cloneable} and {@code java.io.Serializable} are 1412 * returned in that order. 1413 * 1414 * @throws java.lang.reflect.GenericSignatureFormatError 1415 * if the generic class signature does not conform to the 1416 * format specified in section {@jvms 4.7.9} of <cite>The 1417 * Java Virtual Machine Specification</cite> 1418 * @throws TypeNotPresentException if any of the generic 1419 * superinterfaces refers to a non-existent type declaration 1420 * @throws java.lang.reflect.MalformedParameterizedTypeException 1421 * if any of the generic superinterfaces refer to a parameterized 1422 * type that cannot be instantiated for any reason 1423 * @return an array of interfaces directly implemented by this class 1424 * @since 1.5 1425 */ 1426 public Type[] getGenericInterfaces() { 1427 ClassRepository info = getGenericInfo(); 1428 return (info == null) ? getInterfaces() : info.getSuperInterfaces(); 1429 } 1430 1431 1432 /** 1433 * Returns the {@code Class} representing the component type of an 1434 * array. If this class does not represent an array class this method 1435 * returns null. 1436 * 1437 * @return the {@code Class} representing the component type of this 1438 * class if this class is an array 1439 * @see java.lang.reflect.Array 1440 * @since 1.1 1441 */ 1442 public Class<?> getComponentType() { 1443 // Only return for array types. Storage may be reused for Class for instance types. 1444 if (isArray()) { 1445 return componentType; 1446 } else { 1447 return null; 1448 } 1449 } 1450 1451 private final Class<?> componentType; 1452 1453 /* 1454 * Returns the {@code Class} representing the element type of an array class. 1455 * If this class does not represent an array class, then this method returns 1456 * {@code null}. 1457 */ 1458 private Class<?> elementType() { 1459 if (!isArray()) return null; 1460 1461 Class<?> c = this; 1462 while (c.isArray()) { 1463 c = c.getComponentType(); 1464 } 1465 return c; 1466 } 1467 1468 /** 1469 * Returns the Java language modifiers for this class or interface, encoded 1470 * in an integer. The modifiers consist of the Java Virtual Machine's 1471 * constants for {@code public}, {@code protected}, 1472 * {@code private}, {@code final}, {@code static}, 1473 * {@code abstract} and {@code interface}; they should be decoded 1474 * using the methods of class {@code Modifier}. 1475 * 1476 * <p> If the underlying class is an array class: 1477 * <ul> 1478 * <li> its {@code public}, {@code private} and {@code protected} 1479 * modifiers are the same as those of its component type 1480 * <li> its {@code abstract} and {@code final} modifiers are always 1481 * {@code true} 1482 * <li> its interface modifier is always {@code false}, even when 1483 * the component type is an interface 1484 * <li> its {@code identity} modifier is always true 1485 * </ul> 1486 * If this {@code Class} object represents a primitive type or 1487 * void, its {@code public}, {@code abstract}, and {@code final} 1488 * modifiers are always {@code true}. 1489 * For {@code Class} objects representing void, primitive types, and 1490 * arrays, the values of other modifiers are {@code false} other 1491 * than as specified above. 1492 * 1493 * <p> The modifier encodings are defined in section {@jvms 4.1} 1494 * of <cite>The Java Virtual Machine Specification</cite>. 1495 * 1496 * @return the {@code int} representing the modifiers for this class 1497 * @see java.lang.reflect.Modifier 1498 * @see #accessFlags() 1499 * @see <a 1500 * href="{@docRoot}/java.base/java/lang/reflect/package-summary.html#LanguageJvmModel">Java 1501 * programming language and JVM modeling in core reflection</a> 1502 * @since 1.1 1503 * @jls 8.1.1 Class Modifiers 1504 * @jls 9.1.1 Interface Modifiers 1505 * @jvms 4.1 The {@code ClassFile} Structure 1506 */ 1507 @IntrinsicCandidate 1508 public native int getModifiers(); 1509 1510 /** 1511 * {@return an unmodifiable set of the {@linkplain AccessFlag access 1512 * flags} for this class, possibly empty} 1513 * The {@code AccessFlags} may depend on the class file format version of the class. 1514 * 1515 * <p> If the underlying class is an array class: 1516 * <ul> 1517 * <li> its {@code PUBLIC}, {@code PRIVATE} and {@code PROTECTED} 1518 * access flags are the same as those of its component type 1519 * <li> its {@code ABSTRACT} and {@code FINAL} flags are present 1520 * <li> its {@code INTERFACE} flag is absent, even when the 1521 * component type is an interface 1522 * <li> its {@code identity} modifier is always true 1523 * </ul> 1524 * If this {@code Class} object represents a primitive type or 1525 * void, the flags are {@code PUBLIC}, {@code ABSTRACT}, and 1526 * {@code FINAL}. 1527 * For {@code Class} objects representing void, primitive types, and 1528 * arrays, access flags are absent other than as specified above. 1529 * 1530 * @see #getModifiers() 1531 * @jvms 4.1 The ClassFile Structure 1532 * @jvms 4.7.6 The InnerClasses Attribute 1533 * @since 20 1534 */ 1535 public Set<AccessFlag> accessFlags() { 1536 // Location.CLASS allows SUPER and AccessFlag.MODULE which 1537 // INNER_CLASS forbids. INNER_CLASS allows PRIVATE, PROTECTED, 1538 // and STATIC, which are not allowed on Location.CLASS. 1539 // Use getClassAccessFlagsRaw to expose SUPER status. 1540 var location = (isMemberClass() || isLocalClass() || 1541 isAnonymousClass() || isArray()) ? 1542 AccessFlag.Location.INNER_CLASS : 1543 AccessFlag.Location.CLASS; 1544 int accessFlags = (location == AccessFlag.Location.CLASS) ? 1545 getClassAccessFlagsRaw() : getModifiers(); 1546 if (isArray() && PreviewFeatures.isEnabled()) { 1547 accessFlags |= Modifier.IDENTITY; 1548 } 1549 var cffv = ClassFileFormatVersion.fromMajor(getClassFileVersion() & 0xffff); 1550 if (cffv.compareTo(ClassFileFormatVersion.latest()) >= 0) { 1551 // Ignore unspecified (0x0800) access flag for current version 1552 accessFlags &= ~0x0800; 1553 } 1554 return AccessFlag.maskToAccessFlags(accessFlags, location, cffv); 1555 } 1556 1557 /** 1558 * Gets the signers of this class. 1559 * 1560 * @return the signers of this class, or null if there are no signers. In 1561 * particular, this method returns null if this {@code Class} object represents 1562 * a primitive type or void. 1563 * @since 1.1 1564 */ 1565 1566 public Object[] getSigners() { 1567 var signers = this.signers; 1568 return signers == null ? null : signers.clone(); 1569 } 1570 1571 /** 1572 * Set the signers of this class. 1573 */ 1574 void setSigners(Object[] signers) { 1575 if (!isPrimitive() && !isArray()) { 1576 this.signers = signers; 1577 } 1578 } 1579 1580 /** 1581 * If this {@code Class} object represents a local or anonymous 1582 * class within a method, returns a {@link 1583 * java.lang.reflect.Method Method} object representing the 1584 * immediately enclosing method of the underlying class. Returns 1585 * {@code null} otherwise. 1586 * 1587 * In particular, this method returns {@code null} if the underlying 1588 * class is a local or anonymous class immediately enclosed by a class or 1589 * interface declaration, instance initializer or static initializer. 1590 * 1591 * @return the immediately enclosing method of the underlying class, if 1592 * that class is a local or anonymous class; otherwise {@code null}. 1593 * 1594 * @throws SecurityException 1595 * If a security manager, <i>s</i>, is present and any of the 1596 * following conditions is met: 1597 * 1598 * <ul> 1599 * 1600 * <li> the caller's class loader is not the same as the 1601 * class loader of the enclosing class and invocation of 1602 * {@link SecurityManager#checkPermission 1603 * s.checkPermission} method with 1604 * {@code RuntimePermission("accessDeclaredMembers")} 1605 * denies access to the methods within the enclosing class 1606 * 1607 * <li> the caller's class loader is not the same as or an 1608 * ancestor of the class loader for the enclosing class and 1609 * invocation of {@link SecurityManager#checkPackageAccess 1610 * s.checkPackageAccess()} denies access to the package 1611 * of the enclosing class 1612 * 1613 * </ul> 1614 * @since 1.5 1615 */ 1616 @CallerSensitive 1617 public Method getEnclosingMethod() throws SecurityException { 1618 EnclosingMethodInfo enclosingInfo = getEnclosingMethodInfo(); 1619 1620 if (enclosingInfo == null) 1621 return null; 1622 else { 1623 if (!enclosingInfo.isMethod()) 1624 return null; 1625 1626 MethodRepository typeInfo = MethodRepository.make(enclosingInfo.getDescriptor(), 1627 getFactory()); 1628 Class<?> returnType = toClass(typeInfo.getReturnType()); 1629 Type [] parameterTypes = typeInfo.getParameterTypes(); 1630 Class<?>[] parameterClasses = new Class<?>[parameterTypes.length]; 1631 1632 // Convert Types to Classes; returned types *should* 1633 // be class objects since the methodDescriptor's used 1634 // don't have generics information 1635 for(int i = 0; i < parameterClasses.length; i++) 1636 parameterClasses[i] = toClass(parameterTypes[i]); 1637 1638 // Perform access check 1639 final Class<?> enclosingCandidate = enclosingInfo.getEnclosingClass(); 1640 @SuppressWarnings("removal") 1641 SecurityManager sm = System.getSecurityManager(); 1642 if (sm != null) { 1643 enclosingCandidate.checkMemberAccess(sm, Member.DECLARED, 1644 Reflection.getCallerClass(), true); 1645 } 1646 Method[] candidates = enclosingCandidate.privateGetDeclaredMethods(false); 1647 1648 /* 1649 * Loop over all declared methods; match method name, 1650 * number of and type of parameters, *and* return 1651 * type. Matching return type is also necessary 1652 * because of covariant returns, etc. 1653 */ 1654 ReflectionFactory fact = getReflectionFactory(); 1655 for (Method m : candidates) { 1656 if (m.getName().equals(enclosingInfo.getName()) && 1657 arrayContentsEq(parameterClasses, 1658 fact.getExecutableSharedParameterTypes(m))) { 1659 // finally, check return type 1660 if (m.getReturnType().equals(returnType)) { 1661 return fact.copyMethod(m); 1662 } 1663 } 1664 } 1665 1666 throw new InternalError("Enclosing method not found"); 1667 } 1668 } 1669 1670 private native Object[] getEnclosingMethod0(); 1671 1672 private EnclosingMethodInfo getEnclosingMethodInfo() { 1673 Object[] enclosingInfo = getEnclosingMethod0(); 1674 if (enclosingInfo == null) 1675 return null; 1676 else { 1677 return new EnclosingMethodInfo(enclosingInfo); 1678 } 1679 } 1680 1681 private static final class EnclosingMethodInfo { 1682 private final Class<?> enclosingClass; 1683 private final String name; 1684 private final String descriptor; 1685 1686 static void validate(Object[] enclosingInfo) { 1687 if (enclosingInfo.length != 3) 1688 throw new InternalError("Malformed enclosing method information"); 1689 try { 1690 // The array is expected to have three elements: 1691 1692 // the immediately enclosing class 1693 Class<?> enclosingClass = (Class<?>)enclosingInfo[0]; 1694 assert(enclosingClass != null); 1695 1696 // the immediately enclosing method or constructor's 1697 // name (can be null). 1698 String name = (String)enclosingInfo[1]; 1699 1700 // the immediately enclosing method or constructor's 1701 // descriptor (null iff name is). 1702 String descriptor = (String)enclosingInfo[2]; 1703 assert((name != null && descriptor != null) || name == descriptor); 1704 } catch (ClassCastException cce) { 1705 throw new InternalError("Invalid type in enclosing method information", cce); 1706 } 1707 } 1708 1709 EnclosingMethodInfo(Object[] enclosingInfo) { 1710 validate(enclosingInfo); 1711 this.enclosingClass = (Class<?>)enclosingInfo[0]; 1712 this.name = (String)enclosingInfo[1]; 1713 this.descriptor = (String)enclosingInfo[2]; 1714 } 1715 1716 boolean isPartial() { 1717 return enclosingClass == null || name == null || descriptor == null; 1718 } 1719 1720 boolean isConstructor() { return !isPartial() && ConstantDescs.INIT_NAME.equals(name); } 1721 1722 boolean isMethod() { return !isPartial() && !isConstructor() && !ConstantDescs.CLASS_INIT_NAME.equals(name); } 1723 1724 Class<?> getEnclosingClass() { return enclosingClass; } 1725 1726 String getName() { return name; } 1727 1728 String getDescriptor() { return descriptor; } 1729 1730 } 1731 1732 private static Class<?> toClass(Type o) { 1733 if (o instanceof GenericArrayType gat) 1734 return toClass(gat.getGenericComponentType()).arrayType(); 1735 return (Class<?>)o; 1736 } 1737 1738 /** 1739 * If this {@code Class} object represents a local or anonymous 1740 * class within a constructor, returns a {@link 1741 * java.lang.reflect.Constructor Constructor} object representing 1742 * the immediately enclosing constructor of the underlying 1743 * class. Returns {@code null} otherwise. In particular, this 1744 * method returns {@code null} if the underlying class is a local 1745 * or anonymous class immediately enclosed by a class or 1746 * interface declaration, instance initializer or static initializer. 1747 * 1748 * @return the immediately enclosing constructor of the underlying class, if 1749 * that class is a local or anonymous class; otherwise {@code null}. 1750 * @throws SecurityException 1751 * If a security manager, <i>s</i>, is present and any of the 1752 * following conditions is met: 1753 * 1754 * <ul> 1755 * 1756 * <li> the caller's class loader is not the same as the 1757 * class loader of the enclosing class and invocation of 1758 * {@link SecurityManager#checkPermission 1759 * s.checkPermission} method with 1760 * {@code RuntimePermission("accessDeclaredMembers")} 1761 * denies access to the constructors within the enclosing class 1762 * 1763 * <li> the caller's class loader is not the same as or an 1764 * ancestor of the class loader for the enclosing class and 1765 * invocation of {@link SecurityManager#checkPackageAccess 1766 * s.checkPackageAccess()} denies access to the package 1767 * of the enclosing class 1768 * 1769 * </ul> 1770 * @since 1.5 1771 */ 1772 @CallerSensitive 1773 public Constructor<?> getEnclosingConstructor() throws SecurityException { 1774 EnclosingMethodInfo enclosingInfo = getEnclosingMethodInfo(); 1775 1776 if (enclosingInfo == null) 1777 return null; 1778 else { 1779 if (!enclosingInfo.isConstructor()) 1780 return null; 1781 1782 ConstructorRepository typeInfo = ConstructorRepository.make(enclosingInfo.getDescriptor(), 1783 getFactory()); 1784 Type [] parameterTypes = typeInfo.getParameterTypes(); 1785 Class<?>[] parameterClasses = new Class<?>[parameterTypes.length]; 1786 1787 // Convert Types to Classes; returned types *should* 1788 // be class objects since the methodDescriptor's used 1789 // don't have generics information 1790 for(int i = 0; i < parameterClasses.length; i++) 1791 parameterClasses[i] = toClass(parameterTypes[i]); 1792 1793 // Perform access check 1794 final Class<?> enclosingCandidate = enclosingInfo.getEnclosingClass(); 1795 @SuppressWarnings("removal") 1796 SecurityManager sm = System.getSecurityManager(); 1797 if (sm != null) { 1798 enclosingCandidate.checkMemberAccess(sm, Member.DECLARED, 1799 Reflection.getCallerClass(), true); 1800 } 1801 1802 Constructor<?>[] candidates = enclosingCandidate 1803 .privateGetDeclaredConstructors(false); 1804 /* 1805 * Loop over all declared constructors; match number 1806 * of and type of parameters. 1807 */ 1808 ReflectionFactory fact = getReflectionFactory(); 1809 for (Constructor<?> c : candidates) { 1810 if (arrayContentsEq(parameterClasses, 1811 fact.getExecutableSharedParameterTypes(c))) { 1812 return fact.copyConstructor(c); 1813 } 1814 } 1815 1816 throw new InternalError("Enclosing constructor not found"); 1817 } 1818 } 1819 1820 1821 /** 1822 * If the class or interface represented by this {@code Class} object 1823 * is a member of another class, returns the {@code Class} object 1824 * representing the class in which it was declared. This method returns 1825 * null if this class or interface is not a member of any other class. If 1826 * this {@code Class} object represents an array class, a primitive 1827 * type, or void, then this method returns null. 1828 * 1829 * @return the declaring class for this class 1830 * @throws SecurityException 1831 * If a security manager, <i>s</i>, is present and the caller's 1832 * class loader is not the same as or an ancestor of the class 1833 * loader for the declaring class and invocation of {@link 1834 * SecurityManager#checkPackageAccess s.checkPackageAccess()} 1835 * denies access to the package of the declaring class 1836 * @since 1.1 1837 */ 1838 @CallerSensitive 1839 public Class<?> getDeclaringClass() throws SecurityException { 1840 final Class<?> candidate = getDeclaringClass0(); 1841 1842 if (candidate != null) { 1843 @SuppressWarnings("removal") 1844 SecurityManager sm = System.getSecurityManager(); 1845 if (sm != null) { 1846 candidate.checkPackageAccess(sm, 1847 ClassLoader.getClassLoader(Reflection.getCallerClass()), true); 1848 } 1849 } 1850 return candidate; 1851 } 1852 1853 private native Class<?> getDeclaringClass0(); 1854 1855 1856 /** 1857 * Returns the immediately enclosing class of the underlying 1858 * class. If the underlying class is a top level class this 1859 * method returns {@code null}. 1860 * @return the immediately enclosing class of the underlying class 1861 * @throws SecurityException 1862 * If a security manager, <i>s</i>, is present and the caller's 1863 * class loader is not the same as or an ancestor of the class 1864 * loader for the enclosing class and invocation of {@link 1865 * SecurityManager#checkPackageAccess s.checkPackageAccess()} 1866 * denies access to the package of the enclosing class 1867 * @since 1.5 1868 */ 1869 @CallerSensitive 1870 public Class<?> getEnclosingClass() throws SecurityException { 1871 // There are five kinds of classes (or interfaces): 1872 // a) Top level classes 1873 // b) Nested classes (static member classes) 1874 // c) Inner classes (non-static member classes) 1875 // d) Local classes (named classes declared within a method) 1876 // e) Anonymous classes 1877 1878 1879 // JVM Spec 4.7.7: A class must have an EnclosingMethod 1880 // attribute if and only if it is a local class or an 1881 // anonymous class. 1882 EnclosingMethodInfo enclosingInfo = getEnclosingMethodInfo(); 1883 Class<?> enclosingCandidate; 1884 1885 if (enclosingInfo == null) { 1886 // This is a top level or a nested class or an inner class (a, b, or c) 1887 enclosingCandidate = getDeclaringClass0(); 1888 } else { 1889 Class<?> enclosingClass = enclosingInfo.getEnclosingClass(); 1890 // This is a local class or an anonymous class (d or e) 1891 if (enclosingClass == this || enclosingClass == null) 1892 throw new InternalError("Malformed enclosing method information"); 1893 else 1894 enclosingCandidate = enclosingClass; 1895 } 1896 1897 if (enclosingCandidate != null) { 1898 @SuppressWarnings("removal") 1899 SecurityManager sm = System.getSecurityManager(); 1900 if (sm != null) { 1901 enclosingCandidate.checkPackageAccess(sm, 1902 ClassLoader.getClassLoader(Reflection.getCallerClass()), true); 1903 } 1904 } 1905 return enclosingCandidate; 1906 } 1907 1908 /** 1909 * Returns the simple name of the underlying class as given in the 1910 * source code. An empty string is returned if the underlying class is 1911 * {@linkplain #isAnonymousClass() anonymous}. 1912 * A {@linkplain #isSynthetic() synthetic class}, one not present 1913 * in source code, can have a non-empty name including special 1914 * characters, such as "{@code $}". 1915 * 1916 * <p>The simple name of an {@linkplain #isArray() array class} is the simple name of the 1917 * component type with "[]" appended. In particular the simple 1918 * name of an array class whose component type is anonymous is "[]". 1919 * 1920 * @return the simple name of the underlying class 1921 * @since 1.5 1922 */ 1923 public String getSimpleName() { 1924 ReflectionData<T> rd = reflectionData(); 1925 String simpleName = rd.simpleName; 1926 if (simpleName == null) { 1927 rd.simpleName = simpleName = getSimpleName0(); 1928 } 1929 return simpleName; 1930 } 1931 1932 private String getSimpleName0() { 1933 if (isArray()) { 1934 return getComponentType().getSimpleName().concat("[]"); 1935 } 1936 String simpleName = getSimpleBinaryName(); 1937 if (simpleName == null) { // top level class 1938 simpleName = getName(); 1939 simpleName = simpleName.substring(simpleName.lastIndexOf('.') + 1); // strip the package name 1940 } 1941 return simpleName; 1942 } 1943 1944 /** 1945 * Return an informative string for the name of this class or interface. 1946 * 1947 * @return an informative string for the name of this class or interface 1948 * @since 1.8 1949 */ 1950 public String getTypeName() { 1951 if (isArray()) { 1952 try { 1953 Class<?> cl = this; 1954 int dimensions = 0; 1955 do { 1956 dimensions++; 1957 cl = cl.getComponentType(); 1958 } while (cl.isArray()); 1959 return cl.getName().concat("[]".repeat(dimensions)); 1960 } catch (Throwable e) { /*FALLTHRU*/ } 1961 } 1962 return getName(); 1963 } 1964 1965 /** 1966 * Returns the canonical name of the underlying class as 1967 * defined by <cite>The Java Language Specification</cite>. 1968 * Returns {@code null} if the underlying class does not have a canonical 1969 * name. Classes without canonical names include: 1970 * <ul> 1971 * <li>a {@linkplain #isLocalClass() local class} 1972 * <li>a {@linkplain #isAnonymousClass() anonymous class} 1973 * <li>a {@linkplain #isHidden() hidden class} 1974 * <li>an array whose component type does not have a canonical name</li> 1975 * </ul> 1976 * 1977 * The canonical name for a primitive class is the keyword for the 1978 * corresponding primitive type ({@code byte}, {@code short}, 1979 * {@code char}, {@code int}, and so on). 1980 * 1981 * <p>An array type has a canonical name if and only if its 1982 * component type has a canonical name. When an array type has a 1983 * canonical name, it is equal to the canonical name of the 1984 * component type followed by "{@code []}". 1985 * 1986 * @return the canonical name of the underlying class if it exists, and 1987 * {@code null} otherwise. 1988 * @jls 6.7 Fully Qualified Names and Canonical Names 1989 * @since 1.5 1990 */ 1991 public String getCanonicalName() { 1992 ReflectionData<T> rd = reflectionData(); 1993 String canonicalName = rd.canonicalName; 1994 if (canonicalName == null) { 1995 rd.canonicalName = canonicalName = getCanonicalName0(); 1996 } 1997 return canonicalName == ReflectionData.NULL_SENTINEL? null : canonicalName; 1998 } 1999 2000 private String getCanonicalName0() { 2001 if (isArray()) { 2002 String canonicalName = getComponentType().getCanonicalName(); 2003 if (canonicalName != null) 2004 return canonicalName.concat("[]"); 2005 else 2006 return ReflectionData.NULL_SENTINEL; 2007 } 2008 if (isHidden() || isLocalOrAnonymousClass()) 2009 return ReflectionData.NULL_SENTINEL; 2010 Class<?> enclosingClass = getEnclosingClass(); 2011 if (enclosingClass == null) { // top level class 2012 return getName(); 2013 } else { 2014 String enclosingName = enclosingClass.getCanonicalName(); 2015 if (enclosingName == null) 2016 return ReflectionData.NULL_SENTINEL; 2017 String simpleName = getSimpleName(); 2018 return new StringBuilder(enclosingName.length() + simpleName.length() + 1) 2019 .append(enclosingName) 2020 .append('.') 2021 .append(simpleName) 2022 .toString(); 2023 } 2024 } 2025 2026 /** 2027 * Returns {@code true} if and only if the underlying class 2028 * is an anonymous class. 2029 * 2030 * @apiNote 2031 * An anonymous class is not a {@linkplain #isHidden() hidden class}. 2032 * 2033 * @return {@code true} if and only if this class is an anonymous class. 2034 * @since 1.5 2035 * @jls 15.9.5 Anonymous Class Declarations 2036 */ 2037 public boolean isAnonymousClass() { 2038 return !isArray() && isLocalOrAnonymousClass() && 2039 getSimpleBinaryName0() == null; 2040 } 2041 2042 /** 2043 * Returns {@code true} if and only if the underlying class 2044 * is a local class. 2045 * 2046 * @return {@code true} if and only if this class is a local class. 2047 * @since 1.5 2048 * @jls 14.3 Local Class and Interface Declarations 2049 */ 2050 public boolean isLocalClass() { 2051 return isLocalOrAnonymousClass() && 2052 (isArray() || getSimpleBinaryName0() != null); 2053 } 2054 2055 /** 2056 * Returns {@code true} if and only if the underlying class 2057 * is a member class. 2058 * 2059 * @return {@code true} if and only if this class is a member class. 2060 * @since 1.5 2061 * @jls 8.5 Member Class and Interface Declarations 2062 */ 2063 public boolean isMemberClass() { 2064 return !isLocalOrAnonymousClass() && getDeclaringClass0() != null; 2065 } 2066 2067 /** 2068 * Returns the "simple binary name" of the underlying class, i.e., 2069 * the binary name without the leading enclosing class name. 2070 * Returns {@code null} if the underlying class is a top level 2071 * class. 2072 */ 2073 private String getSimpleBinaryName() { 2074 if (isTopLevelClass()) 2075 return null; 2076 String name = getSimpleBinaryName0(); 2077 if (name == null) // anonymous class 2078 return ""; 2079 return name; 2080 } 2081 2082 private native String getSimpleBinaryName0(); 2083 2084 /** 2085 * Returns {@code true} if this is a top level class. Returns {@code false} 2086 * otherwise. 2087 */ 2088 private boolean isTopLevelClass() { 2089 return !isLocalOrAnonymousClass() && getDeclaringClass0() == null; 2090 } 2091 2092 /** 2093 * Returns {@code true} if this is a local class or an anonymous 2094 * class. Returns {@code false} otherwise. 2095 */ 2096 private boolean isLocalOrAnonymousClass() { 2097 // JVM Spec 4.7.7: A class must have an EnclosingMethod 2098 // attribute if and only if it is a local class or an 2099 // anonymous class. 2100 return hasEnclosingMethodInfo(); 2101 } 2102 2103 private boolean hasEnclosingMethodInfo() { 2104 Object[] enclosingInfo = getEnclosingMethod0(); 2105 if (enclosingInfo != null) { 2106 EnclosingMethodInfo.validate(enclosingInfo); 2107 return true; 2108 } 2109 return false; 2110 } 2111 2112 /** 2113 * Returns an array containing {@code Class} objects representing all 2114 * the public classes and interfaces that are members of the class 2115 * represented by this {@code Class} object. This includes public 2116 * class and interface members inherited from superclasses and public class 2117 * and interface members declared by the class. This method returns an 2118 * array of length 0 if this {@code Class} object has no public member 2119 * classes or interfaces. This method also returns an array of length 0 if 2120 * this {@code Class} object represents a primitive type, an array 2121 * class, or void. 2122 * 2123 * @return the array of {@code Class} objects representing the public 2124 * members of this class 2125 * @throws SecurityException 2126 * If a security manager, <i>s</i>, is present and 2127 * the caller's class loader is not the same as or an 2128 * ancestor of the class loader for the current class and 2129 * invocation of {@link SecurityManager#checkPackageAccess 2130 * s.checkPackageAccess()} denies access to the package 2131 * of this class. 2132 * 2133 * @since 1.1 2134 */ 2135 @SuppressWarnings("removal") 2136 @CallerSensitive 2137 public Class<?>[] getClasses() { 2138 SecurityManager sm = System.getSecurityManager(); 2139 if (sm != null) { 2140 checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), false); 2141 } 2142 2143 // Privileged so this implementation can look at DECLARED classes, 2144 // something the caller might not have privilege to do. The code here 2145 // is allowed to look at DECLARED classes because (1) it does not hand 2146 // out anything other than public members and (2) public member access 2147 // has already been ok'd by the SecurityManager. 2148 2149 return java.security.AccessController.doPrivileged( 2150 new java.security.PrivilegedAction<>() { 2151 public Class<?>[] run() { 2152 List<Class<?>> list = new ArrayList<>(); 2153 Class<?> currentClass = Class.this; 2154 while (currentClass != null) { 2155 for (Class<?> m : currentClass.getDeclaredClasses()) { 2156 if (Modifier.isPublic(m.getModifiers())) { 2157 list.add(m); 2158 } 2159 } 2160 currentClass = currentClass.getSuperclass(); 2161 } 2162 return list.toArray(new Class<?>[0]); 2163 } 2164 }); 2165 } 2166 2167 2168 /** 2169 * Returns an array containing {@code Field} objects reflecting all 2170 * the accessible public fields of the class or interface represented by 2171 * this {@code Class} object. 2172 * 2173 * <p> If this {@code Class} object represents a class or interface with 2174 * no accessible public fields, then this method returns an array of length 2175 * 0. 2176 * 2177 * <p> If this {@code Class} object represents a class, then this method 2178 * returns the public fields of the class and of all its superclasses and 2179 * superinterfaces. 2180 * 2181 * <p> If this {@code Class} object represents an interface, then this 2182 * method returns the fields of the interface and of all its 2183 * superinterfaces. 2184 * 2185 * <p> If this {@code Class} object represents an array type, a primitive 2186 * type, or void, then this method returns an array of length 0. 2187 * 2188 * <p> The elements in the returned array are not sorted and are not in any 2189 * particular order. 2190 * 2191 * @return the array of {@code Field} objects representing the 2192 * public fields 2193 * @throws SecurityException 2194 * If a security manager, <i>s</i>, is present and 2195 * the caller's class loader is not the same as or an 2196 * ancestor of the class loader for the current class and 2197 * invocation of {@link SecurityManager#checkPackageAccess 2198 * s.checkPackageAccess()} denies access to the package 2199 * of this class. 2200 * 2201 * @since 1.1 2202 * @jls 8.2 Class Members 2203 * @jls 8.3 Field Declarations 2204 */ 2205 @CallerSensitive 2206 public Field[] getFields() throws SecurityException { 2207 @SuppressWarnings("removal") 2208 SecurityManager sm = System.getSecurityManager(); 2209 if (sm != null) { 2210 checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true); 2211 } 2212 return copyFields(privateGetPublicFields()); 2213 } 2214 2215 2216 /** 2217 * Returns an array containing {@code Method} objects reflecting all the 2218 * public methods of the class or interface represented by this {@code 2219 * Class} object, including those declared by the class or interface and 2220 * those inherited from superclasses and superinterfaces. 2221 * 2222 * <p> If this {@code Class} object represents an array type, then the 2223 * returned array has a {@code Method} object for each of the public 2224 * methods inherited by the array type from {@code Object}. It does not 2225 * contain a {@code Method} object for {@code clone()}. 2226 * 2227 * <p> If this {@code Class} object represents an interface then the 2228 * returned array does not contain any implicitly declared methods from 2229 * {@code Object}. Therefore, if no methods are explicitly declared in 2230 * this interface or any of its superinterfaces then the returned array 2231 * has length 0. (Note that a {@code Class} object which represents a class 2232 * always has public methods, inherited from {@code Object}.) 2233 * 2234 * <p> The returned array never contains methods with names {@value 2235 * ConstantDescs#INIT_NAME} or {@value ConstantDescs#CLASS_INIT_NAME}. 2236 * 2237 * <p> The elements in the returned array are not sorted and are not in any 2238 * particular order. 2239 * 2240 * <p> Generally, the result is computed as with the following 4 step algorithm. 2241 * Let C be the class or interface represented by this {@code Class} object: 2242 * <ol> 2243 * <li> A union of methods is composed of: 2244 * <ol type="a"> 2245 * <li> C's declared public instance and static methods as returned by 2246 * {@link #getDeclaredMethods()} and filtered to include only public 2247 * methods.</li> 2248 * <li> If C is a class other than {@code Object}, then include the result 2249 * of invoking this algorithm recursively on the superclass of C.</li> 2250 * <li> Include the results of invoking this algorithm recursively on all 2251 * direct superinterfaces of C, but include only instance methods.</li> 2252 * </ol></li> 2253 * <li> Union from step 1 is partitioned into subsets of methods with same 2254 * signature (name, parameter types) and return type.</li> 2255 * <li> Within each such subset only the most specific methods are selected. 2256 * Let method M be a method from a set of methods with same signature 2257 * and return type. M is most specific if there is no such method 2258 * N != M from the same set, such that N is more specific than M. 2259 * N is more specific than M if: 2260 * <ol type="a"> 2261 * <li> N is declared by a class and M is declared by an interface; or</li> 2262 * <li> N and M are both declared by classes or both by interfaces and 2263 * N's declaring type is the same as or a subtype of M's declaring type 2264 * (clearly, if M's and N's declaring types are the same type, then 2265 * M and N are the same method).</li> 2266 * </ol></li> 2267 * <li> The result of this algorithm is the union of all selected methods from 2268 * step 3.</li> 2269 * </ol> 2270 * 2271 * @apiNote There may be more than one method with a particular name 2272 * and parameter types in a class because while the Java language forbids a 2273 * class to declare multiple methods with the same signature but different 2274 * return types, the Java virtual machine does not. This 2275 * increased flexibility in the virtual machine can be used to 2276 * implement various language features. For example, covariant 2277 * returns can be implemented with {@linkplain 2278 * java.lang.reflect.Method#isBridge bridge methods}; the bridge 2279 * method and the overriding method would have the same 2280 * signature but different return types. 2281 * 2282 * @return the array of {@code Method} objects representing the 2283 * public methods of this class 2284 * @throws SecurityException 2285 * If a security manager, <i>s</i>, is present and 2286 * the caller's class loader is not the same as or an 2287 * ancestor of the class loader for the current class and 2288 * invocation of {@link SecurityManager#checkPackageAccess 2289 * s.checkPackageAccess()} denies access to the package 2290 * of this class. 2291 * 2292 * @jls 8.2 Class Members 2293 * @jls 8.4 Method Declarations 2294 * @since 1.1 2295 */ 2296 @CallerSensitive 2297 public Method[] getMethods() throws SecurityException { 2298 @SuppressWarnings("removal") 2299 SecurityManager sm = System.getSecurityManager(); 2300 if (sm != null) { 2301 checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true); 2302 } 2303 return copyMethods(privateGetPublicMethods()); 2304 } 2305 2306 2307 /** 2308 * Returns an array containing {@code Constructor} objects reflecting 2309 * all the public constructors of the class represented by this 2310 * {@code Class} object. An array of length 0 is returned if the 2311 * class has no public constructors, or if the class is an array class, or 2312 * if the class reflects a primitive type or void. 2313 * 2314 * @apiNote 2315 * While this method returns an array of {@code 2316 * Constructor<T>} objects (that is an array of constructors from 2317 * this class), the return type of this method is {@code 2318 * Constructor<?>[]} and <em>not</em> {@code Constructor<T>[]} as 2319 * might be expected. This less informative return type is 2320 * necessary since after being returned from this method, the 2321 * array could be modified to hold {@code Constructor} objects for 2322 * different classes, which would violate the type guarantees of 2323 * {@code Constructor<T>[]}. 2324 * 2325 * @return the array of {@code Constructor} objects representing the 2326 * public constructors of this class 2327 * @throws SecurityException 2328 * If a security manager, <i>s</i>, is present and 2329 * the caller's class loader is not the same as or an 2330 * ancestor of the class loader for the current class and 2331 * invocation of {@link SecurityManager#checkPackageAccess 2332 * s.checkPackageAccess()} denies access to the package 2333 * of this class. 2334 * 2335 * @see #getDeclaredConstructors() 2336 * @since 1.1 2337 */ 2338 @CallerSensitive 2339 public Constructor<?>[] getConstructors() throws SecurityException { 2340 @SuppressWarnings("removal") 2341 SecurityManager sm = System.getSecurityManager(); 2342 if (sm != null) { 2343 checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true); 2344 } 2345 return copyConstructors(privateGetDeclaredConstructors(true)); 2346 } 2347 2348 2349 /** 2350 * Returns a {@code Field} object that reflects the specified public member 2351 * field of the class or interface represented by this {@code Class} 2352 * object. The {@code name} parameter is a {@code String} specifying the 2353 * simple name of the desired field. 2354 * 2355 * <p> The field to be reflected is determined by the algorithm that 2356 * follows. Let C be the class or interface represented by this {@code Class} object: 2357 * 2358 * <OL> 2359 * <LI> If C declares a public field with the name specified, that is the 2360 * field to be reflected.</LI> 2361 * <LI> If no field was found in step 1 above, this algorithm is applied 2362 * recursively to each direct superinterface of C. The direct 2363 * superinterfaces are searched in the order they were declared.</LI> 2364 * <LI> If no field was found in steps 1 and 2 above, and C has a 2365 * superclass S, then this algorithm is invoked recursively upon S. 2366 * If C has no superclass, then a {@code NoSuchFieldException} 2367 * is thrown.</LI> 2368 * </OL> 2369 * 2370 * <p> If this {@code Class} object represents an array type, then this 2371 * method does not find the {@code length} field of the array type. 2372 * 2373 * @param name the field name 2374 * @return the {@code Field} object of this class specified by 2375 * {@code name} 2376 * @throws NoSuchFieldException if a field with the specified name is 2377 * not found. 2378 * @throws NullPointerException if {@code name} is {@code null} 2379 * @throws SecurityException 2380 * If a security manager, <i>s</i>, is present and 2381 * the caller's class loader is not the same as or an 2382 * ancestor of the class loader for the current class and 2383 * invocation of {@link SecurityManager#checkPackageAccess 2384 * s.checkPackageAccess()} denies access to the package 2385 * of this class. 2386 * 2387 * @since 1.1 2388 * @jls 8.2 Class Members 2389 * @jls 8.3 Field Declarations 2390 */ 2391 @CallerSensitive 2392 public Field getField(String name) 2393 throws NoSuchFieldException, SecurityException { 2394 Objects.requireNonNull(name); 2395 @SuppressWarnings("removal") 2396 SecurityManager sm = System.getSecurityManager(); 2397 if (sm != null) { 2398 checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true); 2399 } 2400 Field field = getField0(name); 2401 if (field == null) { 2402 throw new NoSuchFieldException(name); 2403 } 2404 return getReflectionFactory().copyField(field); 2405 } 2406 2407 2408 /** 2409 * Returns a {@code Method} object that reflects the specified public 2410 * member method of the class or interface represented by this 2411 * {@code Class} object. The {@code name} parameter is a 2412 * {@code String} specifying the simple name of the desired method. The 2413 * {@code parameterTypes} parameter is an array of {@code Class} 2414 * objects that identify the method's formal parameter types, in declared 2415 * order. If {@code parameterTypes} is {@code null}, it is 2416 * treated as if it were an empty array. 2417 * 2418 * <p> If this {@code Class} object represents an array type, then this 2419 * method finds any public method inherited by the array type from 2420 * {@code Object} except method {@code clone()}. 2421 * 2422 * <p> If this {@code Class} object represents an interface then this 2423 * method does not find any implicitly declared method from 2424 * {@code Object}. Therefore, if no methods are explicitly declared in 2425 * this interface or any of its superinterfaces, then this method does not 2426 * find any method. 2427 * 2428 * <p> This method does not find any method with name {@value 2429 * ConstantDescs#INIT_NAME} or {@value ConstantDescs#CLASS_INIT_NAME}. 2430 * 2431 * <p> Generally, the method to be reflected is determined by the 4 step 2432 * algorithm that follows. 2433 * Let C be the class or interface represented by this {@code Class} object: 2434 * <ol> 2435 * <li> A union of methods is composed of: 2436 * <ol type="a"> 2437 * <li> C's declared public instance and static methods as returned by 2438 * {@link #getDeclaredMethods()} and filtered to include only public 2439 * methods that match given {@code name} and {@code parameterTypes}</li> 2440 * <li> If C is a class other than {@code Object}, then include the result 2441 * of invoking this algorithm recursively on the superclass of C.</li> 2442 * <li> Include the results of invoking this algorithm recursively on all 2443 * direct superinterfaces of C, but include only instance methods.</li> 2444 * </ol></li> 2445 * <li> This union is partitioned into subsets of methods with same 2446 * return type (the selection of methods from step 1 also guarantees that 2447 * they have the same method name and parameter types).</li> 2448 * <li> Within each such subset only the most specific methods are selected. 2449 * Let method M be a method from a set of methods with same VM 2450 * signature (return type, name, parameter types). 2451 * M is most specific if there is no such method N != M from the same 2452 * set, such that N is more specific than M. N is more specific than M 2453 * if: 2454 * <ol type="a"> 2455 * <li> N is declared by a class and M is declared by an interface; or</li> 2456 * <li> N and M are both declared by classes or both by interfaces and 2457 * N's declaring type is the same as or a subtype of M's declaring type 2458 * (clearly, if M's and N's declaring types are the same type, then 2459 * M and N are the same method).</li> 2460 * </ol></li> 2461 * <li> The result of this algorithm is chosen arbitrarily from the methods 2462 * with most specific return type among all selected methods from step 3. 2463 * Let R be a return type of a method M from the set of all selected methods 2464 * from step 3. M is a method with most specific return type if there is 2465 * no such method N != M from the same set, having return type S != R, 2466 * such that S is a subtype of R as determined by 2467 * R.class.{@link #isAssignableFrom}(S.class). 2468 * </ol> 2469 * 2470 * @apiNote There may be more than one method with matching name and 2471 * parameter types in a class because while the Java language forbids a 2472 * class to declare multiple methods with the same signature but different 2473 * return types, the Java virtual machine does not. This 2474 * increased flexibility in the virtual machine can be used to 2475 * implement various language features. For example, covariant 2476 * returns can be implemented with {@linkplain 2477 * java.lang.reflect.Method#isBridge bridge methods}; the bridge 2478 * method and the overriding method would have the same 2479 * signature but different return types. This method would return the 2480 * overriding method as it would have a more specific return type. 2481 * 2482 * @param name the name of the method 2483 * @param parameterTypes the list of parameters 2484 * @return the {@code Method} object that matches the specified 2485 * {@code name} and {@code parameterTypes} 2486 * @throws NoSuchMethodException if a matching method is not found 2487 * or if the name is {@value ConstantDescs#INIT_NAME} or 2488 * {@value ConstantDescs#CLASS_INIT_NAME}. 2489 * @throws NullPointerException if {@code name} is {@code null} 2490 * @throws SecurityException 2491 * If a security manager, <i>s</i>, is present and 2492 * the caller's class loader is not the same as or an 2493 * ancestor of the class loader for the current class and 2494 * invocation of {@link SecurityManager#checkPackageAccess 2495 * s.checkPackageAccess()} denies access to the package 2496 * of this class. 2497 * 2498 * @jls 8.2 Class Members 2499 * @jls 8.4 Method Declarations 2500 * @since 1.1 2501 */ 2502 @CallerSensitive 2503 public Method getMethod(String name, Class<?>... parameterTypes) 2504 throws NoSuchMethodException, SecurityException { 2505 Objects.requireNonNull(name); 2506 @SuppressWarnings("removal") 2507 SecurityManager sm = System.getSecurityManager(); 2508 if (sm != null) { 2509 checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true); 2510 } 2511 Method method = getMethod0(name, parameterTypes); 2512 if (method == null) { 2513 throw new NoSuchMethodException(methodToString(name, parameterTypes)); 2514 } 2515 return getReflectionFactory().copyMethod(method); 2516 } 2517 2518 /** 2519 * Returns a {@code Constructor} object that reflects the specified 2520 * public constructor of the class represented by this {@code Class} 2521 * object. The {@code parameterTypes} parameter is an array of 2522 * {@code Class} objects that identify the constructor's formal 2523 * parameter types, in declared order. 2524 * 2525 * If this {@code Class} object represents an inner class 2526 * declared in a non-static context, the formal parameter types 2527 * include the explicit enclosing instance as the first parameter. 2528 * 2529 * <p> The constructor to reflect is the public constructor of the class 2530 * represented by this {@code Class} object whose formal parameter 2531 * types match those specified by {@code parameterTypes}. 2532 * 2533 * @param parameterTypes the parameter array 2534 * @return the {@code Constructor} object of the public constructor that 2535 * matches the specified {@code parameterTypes} 2536 * @throws NoSuchMethodException if a matching constructor is not found, 2537 * including when this {@code Class} object represents 2538 * an interface, a primitive type, an array class, or void. 2539 * @throws SecurityException 2540 * If a security manager, <i>s</i>, is present and 2541 * the caller's class loader is not the same as or an 2542 * ancestor of the class loader for the current class and 2543 * invocation of {@link SecurityManager#checkPackageAccess 2544 * s.checkPackageAccess()} denies access to the package 2545 * of this class. 2546 * 2547 * @see #getDeclaredConstructor(Class<?>[]) 2548 * @since 1.1 2549 */ 2550 @CallerSensitive 2551 public Constructor<T> getConstructor(Class<?>... parameterTypes) 2552 throws NoSuchMethodException, SecurityException 2553 { 2554 @SuppressWarnings("removal") 2555 SecurityManager sm = System.getSecurityManager(); 2556 if (sm != null) { 2557 checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true); 2558 } 2559 return getReflectionFactory().copyConstructor( 2560 getConstructor0(parameterTypes, Member.PUBLIC)); 2561 } 2562 2563 2564 /** 2565 * Returns an array of {@code Class} objects reflecting all the 2566 * classes and interfaces declared as members of the class represented by 2567 * this {@code Class} object. This includes public, protected, default 2568 * (package) access, and private classes and interfaces declared by the 2569 * class, but excludes inherited classes and interfaces. This method 2570 * returns an array of length 0 if the class declares no classes or 2571 * interfaces as members, or if this {@code Class} object represents a 2572 * primitive type, an array class, or void. 2573 * 2574 * @return the array of {@code Class} objects representing all the 2575 * declared members of this class 2576 * @throws SecurityException 2577 * If a security manager, <i>s</i>, is present and any of the 2578 * following conditions is met: 2579 * 2580 * <ul> 2581 * 2582 * <li> the caller's class loader is not the same as the 2583 * class loader of this class and invocation of 2584 * {@link SecurityManager#checkPermission 2585 * s.checkPermission} method with 2586 * {@code RuntimePermission("accessDeclaredMembers")} 2587 * denies access to the declared classes within this class 2588 * 2589 * <li> the caller's class loader is not the same as or an 2590 * ancestor of the class loader for the current class and 2591 * invocation of {@link SecurityManager#checkPackageAccess 2592 * s.checkPackageAccess()} denies access to the package 2593 * of this class 2594 * 2595 * </ul> 2596 * 2597 * @since 1.1 2598 * @jls 8.5 Member Class and Interface Declarations 2599 */ 2600 @CallerSensitive 2601 public Class<?>[] getDeclaredClasses() throws SecurityException { 2602 @SuppressWarnings("removal") 2603 SecurityManager sm = System.getSecurityManager(); 2604 if (sm != null) { 2605 checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), false); 2606 } 2607 return getDeclaredClasses0(); 2608 } 2609 2610 2611 /** 2612 * Returns an array of {@code Field} objects reflecting all the fields 2613 * declared by the class or interface represented by this 2614 * {@code Class} object. This includes public, protected, default 2615 * (package) access, and private fields, but excludes inherited fields. 2616 * 2617 * <p> If this {@code Class} object represents a class or interface with no 2618 * declared fields, then this method returns an array of length 0. 2619 * 2620 * <p> If this {@code Class} object represents an array type, a primitive 2621 * type, or void, then this method returns an array of length 0. 2622 * 2623 * <p> The elements in the returned array are not sorted and are not in any 2624 * particular order. 2625 * 2626 * @return the array of {@code Field} objects representing all the 2627 * declared fields of this class 2628 * @throws SecurityException 2629 * If a security manager, <i>s</i>, is present and any of the 2630 * following conditions is met: 2631 * 2632 * <ul> 2633 * 2634 * <li> the caller's class loader is not the same as the 2635 * class loader of this class and invocation of 2636 * {@link SecurityManager#checkPermission 2637 * s.checkPermission} method with 2638 * {@code RuntimePermission("accessDeclaredMembers")} 2639 * denies access to the declared fields within this class 2640 * 2641 * <li> the caller's class loader is not the same as or an 2642 * ancestor of the class loader for the current class and 2643 * invocation of {@link SecurityManager#checkPackageAccess 2644 * s.checkPackageAccess()} denies access to the package 2645 * of this class 2646 * 2647 * </ul> 2648 * 2649 * @since 1.1 2650 * @jls 8.2 Class Members 2651 * @jls 8.3 Field Declarations 2652 */ 2653 @CallerSensitive 2654 public Field[] getDeclaredFields() throws SecurityException { 2655 @SuppressWarnings("removal") 2656 SecurityManager sm = System.getSecurityManager(); 2657 if (sm != null) { 2658 checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true); 2659 } 2660 return copyFields(privateGetDeclaredFields(false)); 2661 } 2662 2663 /** 2664 * Returns an array of {@code RecordComponent} objects representing all the 2665 * record components of this record class, or {@code null} if this class is 2666 * not a record class. 2667 * 2668 * <p> The components are returned in the same order that they are declared 2669 * in the record header. The array is empty if this record class has no 2670 * components. If the class is not a record class, that is {@link 2671 * #isRecord()} returns {@code false}, then this method returns {@code null}. 2672 * Conversely, if {@link #isRecord()} returns {@code true}, then this method 2673 * returns a non-null value. 2674 * 2675 * @apiNote 2676 * <p> The following method can be used to find the record canonical constructor: 2677 * 2678 * {@snippet lang="java" : 2679 * static <T extends Record> Constructor<T> getCanonicalConstructor(Class<T> cls) 2680 * throws NoSuchMethodException { 2681 * Class<?>[] paramTypes = 2682 * Arrays.stream(cls.getRecordComponents()) 2683 * .map(RecordComponent::getType) 2684 * .toArray(Class<?>[]::new); 2685 * return cls.getDeclaredConstructor(paramTypes); 2686 * }} 2687 * 2688 * @return An array of {@code RecordComponent} objects representing all the 2689 * record components of this record class, or {@code null} if this 2690 * class is not a record class 2691 * @throws SecurityException 2692 * If a security manager, <i>s</i>, is present and any of the 2693 * following conditions is met: 2694 * 2695 * <ul> 2696 * 2697 * <li> the caller's class loader is not the same as the 2698 * class loader of this class and invocation of 2699 * {@link SecurityManager#checkPermission 2700 * s.checkPermission} method with 2701 * {@code RuntimePermission("accessDeclaredMembers")} 2702 * denies access to the declared methods within this class 2703 * 2704 * <li> the caller's class loader is not the same as or an 2705 * ancestor of the class loader for the current class and 2706 * invocation of {@link SecurityManager#checkPackageAccess 2707 * s.checkPackageAccess()} denies access to the package 2708 * of this class 2709 * 2710 * </ul> 2711 * 2712 * @jls 8.10 Record Classes 2713 * @since 16 2714 */ 2715 @CallerSensitive 2716 public RecordComponent[] getRecordComponents() { 2717 @SuppressWarnings("removal") 2718 SecurityManager sm = System.getSecurityManager(); 2719 if (sm != null) { 2720 checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true); 2721 } 2722 if (!isRecord()) { 2723 return null; 2724 } 2725 return getRecordComponents0(); 2726 } 2727 2728 /** 2729 * Returns an array containing {@code Method} objects reflecting all the 2730 * declared methods of the class or interface represented by this {@code 2731 * Class} object, including public, protected, default (package) 2732 * access, and private methods, but excluding inherited methods. 2733 * The declared methods may include methods <em>not</em> in the 2734 * source of the class or interface, including {@linkplain 2735 * Method#isBridge bridge methods} and other {@linkplain 2736 * Executable#isSynthetic synthetic} methods added by compilers. 2737 * 2738 * <p> If this {@code Class} object represents a class or interface that 2739 * has multiple declared methods with the same name and parameter types, 2740 * but different return types, then the returned array has a {@code Method} 2741 * object for each such method. 2742 * 2743 * <p> If this {@code Class} object represents a class or interface that 2744 * has a class initialization method {@value ConstantDescs#CLASS_INIT_NAME}, 2745 * then the returned array does <em>not</em> have a corresponding {@code 2746 * Method} object. 2747 * 2748 * <p> If this {@code Class} object represents a class or interface with no 2749 * declared methods, then the returned array has length 0. 2750 * 2751 * <p> If this {@code Class} object represents an array type, a primitive 2752 * type, or void, then the returned array has length 0. 2753 * 2754 * <p> The elements in the returned array are not sorted and are not in any 2755 * particular order. 2756 * 2757 * @return the array of {@code Method} objects representing all the 2758 * declared methods of this class 2759 * @throws SecurityException 2760 * If a security manager, <i>s</i>, is present and any of the 2761 * following conditions is met: 2762 * 2763 * <ul> 2764 * 2765 * <li> the caller's class loader is not the same as the 2766 * class loader of this class and invocation of 2767 * {@link SecurityManager#checkPermission 2768 * s.checkPermission} method with 2769 * {@code RuntimePermission("accessDeclaredMembers")} 2770 * denies access to the declared methods within this class 2771 * 2772 * <li> the caller's class loader is not the same as or an 2773 * ancestor of the class loader for the current class and 2774 * invocation of {@link SecurityManager#checkPackageAccess 2775 * s.checkPackageAccess()} denies access to the package 2776 * of this class 2777 * 2778 * </ul> 2779 * 2780 * @jls 8.2 Class Members 2781 * @jls 8.4 Method Declarations 2782 * @see <a 2783 * href="{@docRoot}/java.base/java/lang/reflect/package-summary.html#LanguageJvmModel">Java 2784 * programming language and JVM modeling in core reflection</a> 2785 * @since 1.1 2786 */ 2787 @CallerSensitive 2788 public Method[] getDeclaredMethods() throws SecurityException { 2789 @SuppressWarnings("removal") 2790 SecurityManager sm = System.getSecurityManager(); 2791 if (sm != null) { 2792 checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true); 2793 } 2794 return copyMethods(privateGetDeclaredMethods(false)); 2795 } 2796 2797 /** 2798 * Returns an array of {@code Constructor} objects reflecting all the 2799 * constructors implicitly or explicitly declared by the class represented by this 2800 * {@code Class} object. These are public, protected, default 2801 * (package) access, and private constructors. The elements in the array 2802 * returned are not sorted and are not in any particular order. If the 2803 * class has a default constructor (JLS {@jls 8.8.9}), it is included in the returned array. 2804 * If a record class has a canonical constructor (JLS {@jls 2805 * 8.10.4.1}, {@jls 8.10.4.2}), it is included in the returned array. 2806 * 2807 * This method returns an array of length 0 if this {@code Class} 2808 * object represents an interface, a primitive type, an array class, or 2809 * void. 2810 * 2811 * @return the array of {@code Constructor} objects representing all the 2812 * declared constructors of this class 2813 * @throws SecurityException 2814 * If a security manager, <i>s</i>, is present and any of the 2815 * following conditions is met: 2816 * 2817 * <ul> 2818 * 2819 * <li> the caller's class loader is not the same as the 2820 * class loader of this class and invocation of 2821 * {@link SecurityManager#checkPermission 2822 * s.checkPermission} method with 2823 * {@code RuntimePermission("accessDeclaredMembers")} 2824 * denies access to the declared constructors within this class 2825 * 2826 * <li> the caller's class loader is not the same as or an 2827 * ancestor of the class loader for the current class and 2828 * invocation of {@link SecurityManager#checkPackageAccess 2829 * s.checkPackageAccess()} denies access to the package 2830 * of this class 2831 * 2832 * </ul> 2833 * 2834 * @since 1.1 2835 * @see #getConstructors() 2836 * @jls 8.8 Constructor Declarations 2837 */ 2838 @CallerSensitive 2839 public Constructor<?>[] getDeclaredConstructors() throws SecurityException { 2840 @SuppressWarnings("removal") 2841 SecurityManager sm = System.getSecurityManager(); 2842 if (sm != null) { 2843 checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true); 2844 } 2845 return copyConstructors(privateGetDeclaredConstructors(false)); 2846 } 2847 2848 2849 /** 2850 * Returns a {@code Field} object that reflects the specified declared 2851 * field of the class or interface represented by this {@code Class} 2852 * object. The {@code name} parameter is a {@code String} that specifies 2853 * the simple name of the desired field. 2854 * 2855 * <p> If this {@code Class} object represents an array type, then this 2856 * method does not find the {@code length} field of the array type. 2857 * 2858 * @param name the name of the field 2859 * @return the {@code Field} object for the specified field in this 2860 * class 2861 * @throws NoSuchFieldException if a field with the specified name is 2862 * not found. 2863 * @throws NullPointerException if {@code name} is {@code null} 2864 * @throws SecurityException 2865 * If a security manager, <i>s</i>, is present and any of the 2866 * following conditions is met: 2867 * 2868 * <ul> 2869 * 2870 * <li> the caller's class loader is not the same as the 2871 * class loader of this class and invocation of 2872 * {@link SecurityManager#checkPermission 2873 * s.checkPermission} method with 2874 * {@code RuntimePermission("accessDeclaredMembers")} 2875 * denies access to the declared field 2876 * 2877 * <li> the caller's class loader is not the same as or an 2878 * ancestor of the class loader for the current class and 2879 * invocation of {@link SecurityManager#checkPackageAccess 2880 * s.checkPackageAccess()} denies access to the package 2881 * of this class 2882 * 2883 * </ul> 2884 * 2885 * @since 1.1 2886 * @jls 8.2 Class Members 2887 * @jls 8.3 Field Declarations 2888 */ 2889 @CallerSensitive 2890 public Field getDeclaredField(String name) 2891 throws NoSuchFieldException, SecurityException { 2892 Objects.requireNonNull(name); 2893 @SuppressWarnings("removal") 2894 SecurityManager sm = System.getSecurityManager(); 2895 if (sm != null) { 2896 checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true); 2897 } 2898 Field field = searchFields(privateGetDeclaredFields(false), name); 2899 if (field == null) { 2900 throw new NoSuchFieldException(name); 2901 } 2902 return getReflectionFactory().copyField(field); 2903 } 2904 2905 2906 /** 2907 * Returns a {@code Method} object that reflects the specified 2908 * declared method of the class or interface represented by this 2909 * {@code Class} object. The {@code name} parameter is a 2910 * {@code String} that specifies the simple name of the desired 2911 * method, and the {@code parameterTypes} parameter is an array of 2912 * {@code Class} objects that identify the method's formal parameter 2913 * types, in declared order. If more than one method with the same 2914 * parameter types is declared in a class, and one of these methods has a 2915 * return type that is more specific than any of the others, that method is 2916 * returned; otherwise one of the methods is chosen arbitrarily. If the 2917 * name is {@value ConstantDescs#INIT_NAME} or {@value 2918 * ConstantDescs#CLASS_INIT_NAME} a {@code NoSuchMethodException} 2919 * is raised. 2920 * 2921 * <p> If this {@code Class} object represents an array type, then this 2922 * method does not find the {@code clone()} method. 2923 * 2924 * @param name the name of the method 2925 * @param parameterTypes the parameter array 2926 * @return the {@code Method} object for the method of this class 2927 * matching the specified name and parameters 2928 * @throws NoSuchMethodException if a matching method is not found. 2929 * @throws NullPointerException if {@code name} is {@code null} 2930 * @throws SecurityException 2931 * If a security manager, <i>s</i>, is present and any of the 2932 * following conditions is met: 2933 * 2934 * <ul> 2935 * 2936 * <li> the caller's class loader is not the same as the 2937 * class loader of this class and invocation of 2938 * {@link SecurityManager#checkPermission 2939 * s.checkPermission} method with 2940 * {@code RuntimePermission("accessDeclaredMembers")} 2941 * denies access to the declared method 2942 * 2943 * <li> the caller's class loader is not the same as or an 2944 * ancestor of the class loader for the current class and 2945 * invocation of {@link SecurityManager#checkPackageAccess 2946 * s.checkPackageAccess()} denies access to the package 2947 * of this class 2948 * 2949 * </ul> 2950 * 2951 * @jls 8.2 Class Members 2952 * @jls 8.4 Method Declarations 2953 * @since 1.1 2954 */ 2955 @CallerSensitive 2956 public Method getDeclaredMethod(String name, Class<?>... parameterTypes) 2957 throws NoSuchMethodException, SecurityException { 2958 Objects.requireNonNull(name); 2959 @SuppressWarnings("removal") 2960 SecurityManager sm = System.getSecurityManager(); 2961 if (sm != null) { 2962 checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true); 2963 } 2964 Method method = searchMethods(privateGetDeclaredMethods(false), name, parameterTypes); 2965 if (method == null) { 2966 throw new NoSuchMethodException(methodToString(name, parameterTypes)); 2967 } 2968 return getReflectionFactory().copyMethod(method); 2969 } 2970 2971 /** 2972 * Returns the list of {@code Method} objects for the declared public 2973 * methods of this class or interface that have the specified method name 2974 * and parameter types. 2975 * 2976 * @param name the name of the method 2977 * @param parameterTypes the parameter array 2978 * @return the list of {@code Method} objects for the public methods of 2979 * this class matching the specified name and parameters 2980 */ 2981 List<Method> getDeclaredPublicMethods(String name, Class<?>... parameterTypes) { 2982 Method[] methods = privateGetDeclaredMethods(/* publicOnly */ true); 2983 ReflectionFactory factory = getReflectionFactory(); 2984 List<Method> result = new ArrayList<>(); 2985 for (Method method : methods) { 2986 if (method.getName().equals(name) 2987 && Arrays.equals( 2988 factory.getExecutableSharedParameterTypes(method), 2989 parameterTypes)) { 2990 result.add(factory.copyMethod(method)); 2991 } 2992 } 2993 return result; 2994 } 2995 2996 /** 2997 * Returns the most specific {@code Method} object of this class, super class or 2998 * interface that have the specified method name and parameter types. 2999 * 3000 * @param publicOnly true if only public methods are examined, otherwise all methods 3001 * @param name the name of the method 3002 * @param parameterTypes the parameter array 3003 * @return the {@code Method} object for the method found from this class matching 3004 * the specified name and parameters, or null if not found 3005 */ 3006 Method findMethod(boolean publicOnly, String name, Class<?>... parameterTypes) { 3007 PublicMethods.MethodList res = getMethodsRecursive(name, parameterTypes, true, publicOnly); 3008 return res == null ? null : getReflectionFactory().copyMethod(res.getMostSpecific()); 3009 } 3010 3011 /** 3012 * Returns a {@code Constructor} object that reflects the specified 3013 * constructor of the class represented by this 3014 * {@code Class} object. The {@code parameterTypes} parameter is 3015 * an array of {@code Class} objects that identify the constructor's 3016 * formal parameter types, in declared order. 3017 * 3018 * If this {@code Class} object represents an inner class 3019 * declared in a non-static context, the formal parameter types 3020 * include the explicit enclosing instance as the first parameter. 3021 * 3022 * @param parameterTypes the parameter array 3023 * @return The {@code Constructor} object for the constructor with the 3024 * specified parameter list 3025 * @throws NoSuchMethodException if a matching constructor is not found, 3026 * including when this {@code Class} object represents 3027 * an interface, a primitive type, an array class, or void. 3028 * @throws SecurityException 3029 * If a security manager, <i>s</i>, is present and any of the 3030 * following conditions is met: 3031 * 3032 * <ul> 3033 * 3034 * <li> the caller's class loader is not the same as the 3035 * class loader of this class and invocation of 3036 * {@link SecurityManager#checkPermission 3037 * s.checkPermission} method with 3038 * {@code RuntimePermission("accessDeclaredMembers")} 3039 * denies access to the declared constructor 3040 * 3041 * <li> the caller's class loader is not the same as or an 3042 * ancestor of the class loader for the current class and 3043 * invocation of {@link SecurityManager#checkPackageAccess 3044 * s.checkPackageAccess()} denies access to the package 3045 * of this class 3046 * 3047 * </ul> 3048 * 3049 * @see #getConstructor(Class<?>[]) 3050 * @since 1.1 3051 */ 3052 @CallerSensitive 3053 public Constructor<T> getDeclaredConstructor(Class<?>... parameterTypes) 3054 throws NoSuchMethodException, SecurityException 3055 { 3056 @SuppressWarnings("removal") 3057 SecurityManager sm = System.getSecurityManager(); 3058 if (sm != null) { 3059 checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true); 3060 } 3061 3062 return getReflectionFactory().copyConstructor( 3063 getConstructor0(parameterTypes, Member.DECLARED)); 3064 } 3065 3066 /** 3067 * Finds a resource with a given name. 3068 * 3069 * <p> If this class is in a named {@link Module Module} then this method 3070 * will attempt to find the resource in the module. This is done by 3071 * delegating to the module's class loader {@link 3072 * ClassLoader#findResource(String,String) findResource(String,String)} 3073 * method, invoking it with the module name and the absolute name of the 3074 * resource. Resources in named modules are subject to the rules for 3075 * encapsulation specified in the {@code Module} {@link 3076 * Module#getResourceAsStream getResourceAsStream} method and so this 3077 * method returns {@code null} when the resource is a 3078 * non-"{@code .class}" resource in a package that is not open to the 3079 * caller's module. 3080 * 3081 * <p> Otherwise, if this class is not in a named module then the rules for 3082 * searching resources associated with a given class are implemented by the 3083 * defining {@linkplain ClassLoader class loader} of the class. This method 3084 * delegates to this {@code Class} object's class loader. 3085 * If this {@code Class} object was loaded by the bootstrap class loader, 3086 * the method delegates to {@link ClassLoader#getSystemResourceAsStream}. 3087 * 3088 * <p> Before delegation, an absolute resource name is constructed from the 3089 * given resource name using this algorithm: 3090 * 3091 * <ul> 3092 * 3093 * <li> If the {@code name} begins with a {@code '/'} 3094 * (<code>'\u002f'</code>), then the absolute name of the resource is the 3095 * portion of the {@code name} following the {@code '/'}. 3096 * 3097 * <li> Otherwise, the absolute name is of the following form: 3098 * 3099 * <blockquote> 3100 * {@code modified_package_name/name} 3101 * </blockquote> 3102 * 3103 * <p> Where the {@code modified_package_name} is the package name of this 3104 * object with {@code '/'} substituted for {@code '.'} 3105 * (<code>'\u002e'</code>). 3106 * 3107 * </ul> 3108 * 3109 * @param name name of the desired resource 3110 * @return A {@link java.io.InputStream} object; {@code null} if no 3111 * resource with this name is found, the resource is in a package 3112 * that is not {@linkplain Module#isOpen(String, Module) open} to at 3113 * least the caller module, or access to the resource is denied 3114 * by the security manager. 3115 * @throws NullPointerException If {@code name} is {@code null} 3116 * 3117 * @see Module#getResourceAsStream(String) 3118 * @since 1.1 3119 */ 3120 @CallerSensitive 3121 public InputStream getResourceAsStream(String name) { 3122 name = resolveName(name); 3123 3124 Module thisModule = getModule(); 3125 if (thisModule.isNamed()) { 3126 // check if resource can be located by caller 3127 if (Resources.canEncapsulate(name) 3128 && !isOpenToCaller(name, Reflection.getCallerClass())) { 3129 return null; 3130 } 3131 3132 // resource not encapsulated or in package open to caller 3133 String mn = thisModule.getName(); 3134 ClassLoader cl = classLoader; 3135 try { 3136 3137 // special-case built-in class loaders to avoid the 3138 // need for a URL connection 3139 if (cl == null) { 3140 return BootLoader.findResourceAsStream(mn, name); 3141 } else if (cl instanceof BuiltinClassLoader bcl) { 3142 return bcl.findResourceAsStream(mn, name); 3143 } else { 3144 URL url = cl.findResource(mn, name); 3145 return (url != null) ? url.openStream() : null; 3146 } 3147 3148 } catch (IOException | SecurityException e) { 3149 return null; 3150 } 3151 } 3152 3153 // unnamed module 3154 ClassLoader cl = classLoader; 3155 if (cl == null) { 3156 return ClassLoader.getSystemResourceAsStream(name); 3157 } else { 3158 return cl.getResourceAsStream(name); 3159 } 3160 } 3161 3162 /** 3163 * Finds a resource with a given name. 3164 * 3165 * <p> If this class is in a named {@link Module Module} then this method 3166 * will attempt to find the resource in the module. This is done by 3167 * delegating to the module's class loader {@link 3168 * ClassLoader#findResource(String,String) findResource(String,String)} 3169 * method, invoking it with the module name and the absolute name of the 3170 * resource. Resources in named modules are subject to the rules for 3171 * encapsulation specified in the {@code Module} {@link 3172 * Module#getResourceAsStream getResourceAsStream} method and so this 3173 * method returns {@code null} when the resource is a 3174 * non-"{@code .class}" resource in a package that is not open to the 3175 * caller's module. 3176 * 3177 * <p> Otherwise, if this class is not in a named module then the rules for 3178 * searching resources associated with a given class are implemented by the 3179 * defining {@linkplain ClassLoader class loader} of the class. This method 3180 * delegates to this {@code Class} object's class loader. 3181 * If this {@code Class} object was loaded by the bootstrap class loader, 3182 * the method delegates to {@link ClassLoader#getSystemResource}. 3183 * 3184 * <p> Before delegation, an absolute resource name is constructed from the 3185 * given resource name using this algorithm: 3186 * 3187 * <ul> 3188 * 3189 * <li> If the {@code name} begins with a {@code '/'} 3190 * (<code>'\u002f'</code>), then the absolute name of the resource is the 3191 * portion of the {@code name} following the {@code '/'}. 3192 * 3193 * <li> Otherwise, the absolute name is of the following form: 3194 * 3195 * <blockquote> 3196 * {@code modified_package_name/name} 3197 * </blockquote> 3198 * 3199 * <p> Where the {@code modified_package_name} is the package name of this 3200 * object with {@code '/'} substituted for {@code '.'} 3201 * (<code>'\u002e'</code>). 3202 * 3203 * </ul> 3204 * 3205 * @param name name of the desired resource 3206 * @return A {@link java.net.URL} object; {@code null} if no resource with 3207 * this name is found, the resource cannot be located by a URL, the 3208 * resource is in a package that is not 3209 * {@linkplain Module#isOpen(String, Module) open} to at least the caller 3210 * module, or access to the resource is denied by the security 3211 * manager. 3212 * @throws NullPointerException If {@code name} is {@code null} 3213 * @since 1.1 3214 */ 3215 @CallerSensitive 3216 public URL getResource(String name) { 3217 name = resolveName(name); 3218 3219 Module thisModule = getModule(); 3220 if (thisModule.isNamed()) { 3221 // check if resource can be located by caller 3222 if (Resources.canEncapsulate(name) 3223 && !isOpenToCaller(name, Reflection.getCallerClass())) { 3224 return null; 3225 } 3226 3227 // resource not encapsulated or in package open to caller 3228 String mn = thisModule.getName(); 3229 ClassLoader cl = classLoader; 3230 try { 3231 if (cl == null) { 3232 return BootLoader.findResource(mn, name); 3233 } else { 3234 return cl.findResource(mn, name); 3235 } 3236 } catch (IOException ioe) { 3237 return null; 3238 } 3239 } 3240 3241 // unnamed module 3242 ClassLoader cl = classLoader; 3243 if (cl == null) { 3244 return ClassLoader.getSystemResource(name); 3245 } else { 3246 return cl.getResource(name); 3247 } 3248 } 3249 3250 /** 3251 * Returns true if a resource with the given name can be located by the 3252 * given caller. All resources in a module can be located by code in 3253 * the module. For other callers, then the package needs to be open to 3254 * the caller. 3255 */ 3256 private boolean isOpenToCaller(String name, Class<?> caller) { 3257 // assert getModule().isNamed(); 3258 Module thisModule = getModule(); 3259 Module callerModule = (caller != null) ? caller.getModule() : null; 3260 if (callerModule != thisModule) { 3261 String pn = Resources.toPackageName(name); 3262 if (thisModule.getDescriptor().packages().contains(pn)) { 3263 if (callerModule == null) { 3264 // no caller, return true if the package is open to all modules 3265 return thisModule.isOpen(pn); 3266 } 3267 if (!thisModule.isOpen(pn, callerModule)) { 3268 // package not open to caller 3269 return false; 3270 } 3271 } 3272 } 3273 return true; 3274 } 3275 3276 /** 3277 * Returns the {@code ProtectionDomain} of this class. If there is a 3278 * security manager installed, this method first calls the security 3279 * manager's {@code checkPermission} method with a 3280 * {@code RuntimePermission("getProtectionDomain")} permission to 3281 * ensure it's ok to get the 3282 * {@code ProtectionDomain}. 3283 * 3284 * @return the ProtectionDomain of this class 3285 * 3286 * @throws SecurityException 3287 * if a security manager exists and its 3288 * {@code checkPermission} method doesn't allow 3289 * getting the ProtectionDomain. 3290 * 3291 * @see java.security.ProtectionDomain 3292 * @see SecurityManager#checkPermission 3293 * @see java.lang.RuntimePermission 3294 * @since 1.2 3295 */ 3296 public ProtectionDomain getProtectionDomain() { 3297 @SuppressWarnings("removal") 3298 SecurityManager sm = System.getSecurityManager(); 3299 if (sm != null) { 3300 sm.checkPermission(SecurityConstants.GET_PD_PERMISSION); 3301 } 3302 return protectionDomain(); 3303 } 3304 3305 /** Holder for the protection domain returned when the internal domain is null */ 3306 private static class Holder { 3307 private static final ProtectionDomain allPermDomain; 3308 static { 3309 Permissions perms = new Permissions(); 3310 perms.add(SecurityConstants.ALL_PERMISSION); 3311 allPermDomain = new ProtectionDomain(null, perms); 3312 } 3313 } 3314 3315 // package-private 3316 ProtectionDomain protectionDomain() { 3317 ProtectionDomain pd = getProtectionDomain0(); 3318 if (pd == null) { 3319 return Holder.allPermDomain; 3320 } else { 3321 return pd; 3322 } 3323 } 3324 3325 /** 3326 * Returns the ProtectionDomain of this class. 3327 */ 3328 private native ProtectionDomain getProtectionDomain0(); 3329 3330 /* 3331 * Returns the Class object for the named primitive type. Type parameter T 3332 * avoids redundant casts for trusted code. 3333 */ 3334 static native <T> Class<T> getPrimitiveClass(String name); 3335 3336 /* 3337 * Check if client is allowed to access members. If access is denied, 3338 * throw a SecurityException. 3339 * 3340 * This method also enforces package access. 3341 * 3342 * <p> Default policy: allow all clients access with normal Java access 3343 * control. 3344 * 3345 * <p> NOTE: should only be called if a SecurityManager is installed 3346 */ 3347 private void checkMemberAccess(@SuppressWarnings("removal") SecurityManager sm, int which, 3348 Class<?> caller, boolean checkProxyInterfaces) { 3349 /* Default policy allows access to all {@link Member#PUBLIC} members, 3350 * as well as access to classes that have the same class loader as the caller. 3351 * In all other cases, it requires RuntimePermission("accessDeclaredMembers") 3352 * permission. 3353 */ 3354 final ClassLoader ccl = ClassLoader.getClassLoader(caller); 3355 if (which != Member.PUBLIC) { 3356 final ClassLoader cl = classLoader; 3357 if (ccl != cl) { 3358 sm.checkPermission(SecurityConstants.CHECK_MEMBER_ACCESS_PERMISSION); 3359 } 3360 } 3361 this.checkPackageAccess(sm, ccl, checkProxyInterfaces); 3362 } 3363 3364 /* 3365 * Checks if a client loaded in ClassLoader ccl is allowed to access this 3366 * class under the current package access policy. If access is denied, 3367 * throw a SecurityException. 3368 * 3369 * NOTE: this method should only be called if a SecurityManager is active 3370 */ 3371 private void checkPackageAccess(@SuppressWarnings("removal") SecurityManager sm, final ClassLoader ccl, 3372 boolean checkProxyInterfaces) { 3373 final ClassLoader cl = classLoader; 3374 3375 if (ReflectUtil.needsPackageAccessCheck(ccl, cl)) { 3376 String pkg = this.getPackageName(); 3377 if (!pkg.isEmpty()) { 3378 // skip the package access check on a proxy class in default proxy package 3379 if (!Proxy.isProxyClass(this) || ReflectUtil.isNonPublicProxyClass(this)) { 3380 sm.checkPackageAccess(pkg); 3381 } 3382 } 3383 } 3384 // check package access on the proxy interfaces 3385 if (checkProxyInterfaces && Proxy.isProxyClass(this)) { 3386 ReflectUtil.checkProxyPackageAccess(ccl, this.getInterfaces(/* cloneArray */ false)); 3387 } 3388 } 3389 3390 /* 3391 * Checks if a client loaded in ClassLoader ccl is allowed to access the provided 3392 * classes under the current package access policy. If access is denied, 3393 * throw a SecurityException. 3394 * 3395 * NOTE: this method should only be called if a SecurityManager is active 3396 * classes must be non-empty 3397 * all classes provided must be loaded by the same ClassLoader 3398 * NOTE: this method does not support Proxy classes 3399 */ 3400 private static void checkPackageAccessForPermittedSubclasses(@SuppressWarnings("removal") SecurityManager sm, 3401 final ClassLoader ccl, Class<?>[] subClasses) { 3402 final ClassLoader cl = subClasses[0].classLoader; 3403 3404 if (ReflectUtil.needsPackageAccessCheck(ccl, cl)) { 3405 Set<String> packages = new HashSet<>(); 3406 3407 for (Class<?> c : subClasses) { 3408 if (Proxy.isProxyClass(c)) 3409 throw new InternalError("a permitted subclass should not be a proxy class: " + c); 3410 String pkg = c.getPackageName(); 3411 if (!pkg.isEmpty()) { 3412 packages.add(pkg); 3413 } 3414 } 3415 for (String pkg : packages) { 3416 sm.checkPackageAccess(pkg); 3417 } 3418 } 3419 } 3420 3421 /** 3422 * Add a package name prefix if the name is not absolute. Remove leading "/" 3423 * if name is absolute 3424 */ 3425 private String resolveName(String name) { 3426 if (!name.startsWith("/")) { 3427 String baseName = getPackageName(); 3428 if (!baseName.isEmpty()) { 3429 int len = baseName.length() + 1 + name.length(); 3430 StringBuilder sb = new StringBuilder(len); 3431 name = sb.append(baseName.replace('.', '/')) 3432 .append('/') 3433 .append(name) 3434 .toString(); 3435 } 3436 } else { 3437 name = name.substring(1); 3438 } 3439 return name; 3440 } 3441 3442 /** 3443 * Atomic operations support. 3444 */ 3445 private static class Atomic { 3446 // initialize Unsafe machinery here, since we need to call Class.class instance method 3447 // and have to avoid calling it in the static initializer of the Class class... 3448 private static final Unsafe unsafe = Unsafe.getUnsafe(); 3449 // offset of Class.reflectionData instance field 3450 private static final long reflectionDataOffset 3451 = unsafe.objectFieldOffset(Class.class, "reflectionData"); 3452 // offset of Class.annotationType instance field 3453 private static final long annotationTypeOffset 3454 = unsafe.objectFieldOffset(Class.class, "annotationType"); 3455 // offset of Class.annotationData instance field 3456 private static final long annotationDataOffset 3457 = unsafe.objectFieldOffset(Class.class, "annotationData"); 3458 3459 static <T> boolean casReflectionData(Class<?> clazz, 3460 SoftReference<ReflectionData<T>> oldData, 3461 SoftReference<ReflectionData<T>> newData) { 3462 return unsafe.compareAndSetReference(clazz, reflectionDataOffset, oldData, newData); 3463 } 3464 3465 static boolean casAnnotationType(Class<?> clazz, 3466 AnnotationType oldType, 3467 AnnotationType newType) { 3468 return unsafe.compareAndSetReference(clazz, annotationTypeOffset, oldType, newType); 3469 } 3470 3471 static boolean casAnnotationData(Class<?> clazz, 3472 AnnotationData oldData, 3473 AnnotationData newData) { 3474 return unsafe.compareAndSetReference(clazz, annotationDataOffset, oldData, newData); 3475 } 3476 } 3477 3478 /** 3479 * Reflection support. 3480 */ 3481 3482 // Reflection data caches various derived names and reflective members. Cached 3483 // values may be invalidated when JVM TI RedefineClasses() is called 3484 private static class ReflectionData<T> { 3485 volatile Field[] declaredFields; 3486 volatile Field[] publicFields; 3487 volatile Method[] declaredMethods; 3488 volatile Method[] publicMethods; 3489 volatile Constructor<T>[] declaredConstructors; 3490 volatile Constructor<T>[] publicConstructors; 3491 // Intermediate results for getFields and getMethods 3492 volatile Field[] declaredPublicFields; 3493 volatile Method[] declaredPublicMethods; 3494 volatile Class<?>[] interfaces; 3495 3496 // Cached names 3497 String simpleName; 3498 String canonicalName; 3499 static final String NULL_SENTINEL = new String(); 3500 3501 // Value of classRedefinedCount when we created this ReflectionData instance 3502 final int redefinedCount; 3503 3504 ReflectionData(int redefinedCount) { 3505 this.redefinedCount = redefinedCount; 3506 } 3507 } 3508 3509 private transient volatile SoftReference<ReflectionData<T>> reflectionData; 3510 3511 // Incremented by the VM on each call to JVM TI RedefineClasses() 3512 // that redefines this class or a superclass. 3513 private transient volatile int classRedefinedCount; 3514 3515 // Lazily create and cache ReflectionData 3516 private ReflectionData<T> reflectionData() { 3517 SoftReference<ReflectionData<T>> reflectionData = this.reflectionData; 3518 int classRedefinedCount = this.classRedefinedCount; 3519 ReflectionData<T> rd; 3520 if (reflectionData != null && 3521 (rd = reflectionData.get()) != null && 3522 rd.redefinedCount == classRedefinedCount) { 3523 return rd; 3524 } 3525 // else no SoftReference or cleared SoftReference or stale ReflectionData 3526 // -> create and replace new instance 3527 return newReflectionData(reflectionData, classRedefinedCount); 3528 } 3529 3530 private ReflectionData<T> newReflectionData(SoftReference<ReflectionData<T>> oldReflectionData, 3531 int classRedefinedCount) { 3532 while (true) { 3533 ReflectionData<T> rd = new ReflectionData<>(classRedefinedCount); 3534 // try to CAS it... 3535 if (Atomic.casReflectionData(this, oldReflectionData, new SoftReference<>(rd))) { 3536 return rd; 3537 } 3538 // else retry 3539 oldReflectionData = this.reflectionData; 3540 classRedefinedCount = this.classRedefinedCount; 3541 if (oldReflectionData != null && 3542 (rd = oldReflectionData.get()) != null && 3543 rd.redefinedCount == classRedefinedCount) { 3544 return rd; 3545 } 3546 } 3547 } 3548 3549 // Generic signature handling 3550 private native String getGenericSignature0(); 3551 3552 // Generic info repository; lazily initialized 3553 private transient volatile ClassRepository genericInfo; 3554 3555 // accessor for factory 3556 private GenericsFactory getFactory() { 3557 // create scope and factory 3558 return CoreReflectionFactory.make(this, ClassScope.make(this)); 3559 } 3560 3561 // accessor for generic info repository; 3562 // generic info is lazily initialized 3563 private ClassRepository getGenericInfo() { 3564 ClassRepository genericInfo = this.genericInfo; 3565 if (genericInfo == null) { 3566 String signature = getGenericSignature0(); 3567 if (signature == null) { 3568 genericInfo = ClassRepository.NONE; 3569 } else { 3570 genericInfo = ClassRepository.make(signature, getFactory()); 3571 } 3572 this.genericInfo = genericInfo; 3573 } 3574 return (genericInfo != ClassRepository.NONE) ? genericInfo : null; 3575 } 3576 3577 // Annotations handling 3578 native byte[] getRawAnnotations(); 3579 // Since 1.8 3580 native byte[] getRawTypeAnnotations(); 3581 static byte[] getExecutableTypeAnnotationBytes(Executable ex) { 3582 return getReflectionFactory().getExecutableTypeAnnotationBytes(ex); 3583 } 3584 3585 native ConstantPool getConstantPool(); 3586 3587 // 3588 // 3589 // java.lang.reflect.Field handling 3590 // 3591 // 3592 3593 // Returns an array of "root" fields. These Field objects must NOT 3594 // be propagated to the outside world, but must instead be copied 3595 // via ReflectionFactory.copyField. 3596 private Field[] privateGetDeclaredFields(boolean publicOnly) { 3597 Field[] res; 3598 ReflectionData<T> rd = reflectionData(); 3599 if (rd != null) { 3600 res = publicOnly ? rd.declaredPublicFields : rd.declaredFields; 3601 if (res != null) return res; 3602 } 3603 // No cached value available; request value from VM 3604 res = Reflection.filterFields(this, getDeclaredFields0(publicOnly)); 3605 if (rd != null) { 3606 if (publicOnly) { 3607 rd.declaredPublicFields = res; 3608 } else { 3609 rd.declaredFields = res; 3610 } 3611 } 3612 return res; 3613 } 3614 3615 // Returns an array of "root" fields. These Field objects must NOT 3616 // be propagated to the outside world, but must instead be copied 3617 // via ReflectionFactory.copyField. 3618 private Field[] privateGetPublicFields() { 3619 Field[] res; 3620 ReflectionData<T> rd = reflectionData(); 3621 if (rd != null) { 3622 res = rd.publicFields; 3623 if (res != null) return res; 3624 } 3625 3626 // Use a linked hash set to ensure order is preserved and 3627 // fields from common super interfaces are not duplicated 3628 LinkedHashSet<Field> fields = new LinkedHashSet<>(); 3629 3630 // Local fields 3631 addAll(fields, privateGetDeclaredFields(true)); 3632 3633 // Direct superinterfaces, recursively 3634 for (Class<?> si : getInterfaces(/* cloneArray */ false)) { 3635 addAll(fields, si.privateGetPublicFields()); 3636 } 3637 3638 // Direct superclass, recursively 3639 Class<?> sc = getSuperclass(); 3640 if (sc != null) { 3641 addAll(fields, sc.privateGetPublicFields()); 3642 } 3643 3644 res = fields.toArray(new Field[0]); 3645 if (rd != null) { 3646 rd.publicFields = res; 3647 } 3648 return res; 3649 } 3650 3651 private static void addAll(Collection<Field> c, Field[] o) { 3652 for (Field f : o) { 3653 c.add(f); 3654 } 3655 } 3656 3657 3658 // 3659 // 3660 // java.lang.reflect.Constructor handling 3661 // 3662 // 3663 3664 // Returns an array of "root" constructors. These Constructor 3665 // objects must NOT be propagated to the outside world, but must 3666 // instead be copied via ReflectionFactory.copyConstructor. 3667 private Constructor<T>[] privateGetDeclaredConstructors(boolean publicOnly) { 3668 Constructor<T>[] res; 3669 ReflectionData<T> rd = reflectionData(); 3670 if (rd != null) { 3671 res = publicOnly ? rd.publicConstructors : rd.declaredConstructors; 3672 if (res != null) return res; 3673 } 3674 // No cached value available; request value from VM 3675 if (isInterface()) { 3676 @SuppressWarnings("unchecked") 3677 Constructor<T>[] temporaryRes = (Constructor<T>[]) new Constructor<?>[0]; 3678 res = temporaryRes; 3679 } else { 3680 res = getDeclaredConstructors0(publicOnly); 3681 } 3682 if (rd != null) { 3683 if (publicOnly) { 3684 rd.publicConstructors = res; 3685 } else { 3686 rd.declaredConstructors = res; 3687 } 3688 } 3689 return res; 3690 } 3691 3692 // 3693 // 3694 // java.lang.reflect.Method handling 3695 // 3696 // 3697 3698 // Returns an array of "root" methods. These Method objects must NOT 3699 // be propagated to the outside world, but must instead be copied 3700 // via ReflectionFactory.copyMethod. 3701 private Method[] privateGetDeclaredMethods(boolean publicOnly) { 3702 Method[] res; 3703 ReflectionData<T> rd = reflectionData(); 3704 if (rd != null) { 3705 res = publicOnly ? rd.declaredPublicMethods : rd.declaredMethods; 3706 if (res != null) return res; 3707 } 3708 // No cached value available; request value from VM 3709 res = Reflection.filterMethods(this, getDeclaredMethods0(publicOnly)); 3710 if (rd != null) { 3711 if (publicOnly) { 3712 rd.declaredPublicMethods = res; 3713 } else { 3714 rd.declaredMethods = res; 3715 } 3716 } 3717 return res; 3718 } 3719 3720 // Returns an array of "root" methods. These Method objects must NOT 3721 // be propagated to the outside world, but must instead be copied 3722 // via ReflectionFactory.copyMethod. 3723 private Method[] privateGetPublicMethods() { 3724 Method[] res; 3725 ReflectionData<T> rd = reflectionData(); 3726 if (rd != null) { 3727 res = rd.publicMethods; 3728 if (res != null) return res; 3729 } 3730 3731 // No cached value available; compute value recursively. 3732 // Start by fetching public declared methods... 3733 PublicMethods pms = new PublicMethods(); 3734 for (Method m : privateGetDeclaredMethods(/* publicOnly */ true)) { 3735 pms.merge(m); 3736 } 3737 // ...then recur over superclass methods... 3738 Class<?> sc = getSuperclass(); 3739 if (sc != null) { 3740 for (Method m : sc.privateGetPublicMethods()) { 3741 pms.merge(m); 3742 } 3743 } 3744 // ...and finally over direct superinterfaces. 3745 for (Class<?> intf : getInterfaces(/* cloneArray */ false)) { 3746 for (Method m : intf.privateGetPublicMethods()) { 3747 // static interface methods are not inherited 3748 if (!Modifier.isStatic(m.getModifiers())) { 3749 pms.merge(m); 3750 } 3751 } 3752 } 3753 3754 res = pms.toArray(); 3755 if (rd != null) { 3756 rd.publicMethods = res; 3757 } 3758 return res; 3759 } 3760 3761 3762 // 3763 // Helpers for fetchers of one field, method, or constructor 3764 // 3765 3766 // This method does not copy the returned Field object! 3767 private static Field searchFields(Field[] fields, String name) { 3768 for (Field field : fields) { 3769 if (field.getName().equals(name)) { 3770 return field; 3771 } 3772 } 3773 return null; 3774 } 3775 3776 // Returns a "root" Field object. This Field object must NOT 3777 // be propagated to the outside world, but must instead be copied 3778 // via ReflectionFactory.copyField. 3779 private Field getField0(String name) { 3780 // Note: the intent is that the search algorithm this routine 3781 // uses be equivalent to the ordering imposed by 3782 // privateGetPublicFields(). It fetches only the declared 3783 // public fields for each class, however, to reduce the number 3784 // of Field objects which have to be created for the common 3785 // case where the field being requested is declared in the 3786 // class which is being queried. 3787 Field res; 3788 // Search declared public fields 3789 if ((res = searchFields(privateGetDeclaredFields(true), name)) != null) { 3790 return res; 3791 } 3792 // Direct superinterfaces, recursively 3793 Class<?>[] interfaces = getInterfaces(/* cloneArray */ false); 3794 for (Class<?> c : interfaces) { 3795 if ((res = c.getField0(name)) != null) { 3796 return res; 3797 } 3798 } 3799 // Direct superclass, recursively 3800 if (!isInterface()) { 3801 Class<?> c = getSuperclass(); 3802 if (c != null) { 3803 if ((res = c.getField0(name)) != null) { 3804 return res; 3805 } 3806 } 3807 } 3808 return null; 3809 } 3810 3811 // This method does not copy the returned Method object! 3812 private static Method searchMethods(Method[] methods, 3813 String name, 3814 Class<?>[] parameterTypes) 3815 { 3816 ReflectionFactory fact = getReflectionFactory(); 3817 Method res = null; 3818 for (Method m : methods) { 3819 if (m.getName().equals(name) 3820 && arrayContentsEq(parameterTypes, 3821 fact.getExecutableSharedParameterTypes(m)) 3822 && (res == null 3823 || (res.getReturnType() != m.getReturnType() 3824 && res.getReturnType().isAssignableFrom(m.getReturnType())))) 3825 res = m; 3826 } 3827 return res; 3828 } 3829 3830 private static final Class<?>[] EMPTY_CLASS_ARRAY = new Class<?>[0]; 3831 3832 // Returns a "root" Method object. This Method object must NOT 3833 // be propagated to the outside world, but must instead be copied 3834 // via ReflectionFactory.copyMethod. 3835 private Method getMethod0(String name, Class<?>[] parameterTypes) { 3836 PublicMethods.MethodList res = getMethodsRecursive( 3837 name, 3838 parameterTypes == null ? EMPTY_CLASS_ARRAY : parameterTypes, 3839 /* includeStatic */ true, /* publicOnly */ true); 3840 return res == null ? null : res.getMostSpecific(); 3841 } 3842 3843 // Returns a list of "root" Method objects. These Method objects must NOT 3844 // be propagated to the outside world, but must instead be copied 3845 // via ReflectionFactory.copyMethod. 3846 private PublicMethods.MethodList getMethodsRecursive(String name, 3847 Class<?>[] parameterTypes, 3848 boolean includeStatic, 3849 boolean publicOnly) { 3850 // 1st check declared methods 3851 Method[] methods = privateGetDeclaredMethods(publicOnly); 3852 PublicMethods.MethodList res = PublicMethods.MethodList 3853 .filter(methods, name, parameterTypes, includeStatic); 3854 // if there is at least one match among declared methods, we need not 3855 // search any further as such match surely overrides matching methods 3856 // declared in superclass(es) or interface(s). 3857 if (res != null) { 3858 return res; 3859 } 3860 3861 // if there was no match among declared methods, 3862 // we must consult the superclass (if any) recursively... 3863 Class<?> sc = getSuperclass(); 3864 if (sc != null) { 3865 res = sc.getMethodsRecursive(name, parameterTypes, includeStatic, publicOnly); 3866 } 3867 3868 // ...and coalesce the superclass methods with methods obtained 3869 // from directly implemented interfaces excluding static methods... 3870 for (Class<?> intf : getInterfaces(/* cloneArray */ false)) { 3871 res = PublicMethods.MethodList.merge( 3872 res, intf.getMethodsRecursive(name, parameterTypes, /* includeStatic */ false, publicOnly)); 3873 } 3874 3875 return res; 3876 } 3877 3878 // Returns a "root" Constructor object. This Constructor object must NOT 3879 // be propagated to the outside world, but must instead be copied 3880 // via ReflectionFactory.copyConstructor. 3881 private Constructor<T> getConstructor0(Class<?>[] parameterTypes, 3882 int which) throws NoSuchMethodException 3883 { 3884 ReflectionFactory fact = getReflectionFactory(); 3885 Constructor<T>[] constructors = privateGetDeclaredConstructors((which == Member.PUBLIC)); 3886 for (Constructor<T> constructor : constructors) { 3887 if (arrayContentsEq(parameterTypes, 3888 fact.getExecutableSharedParameterTypes(constructor))) { 3889 return constructor; 3890 } 3891 } 3892 throw new NoSuchMethodException(methodToString("<init>", parameterTypes)); 3893 } 3894 3895 // 3896 // Other helpers and base implementation 3897 // 3898 3899 private static boolean arrayContentsEq(Object[] a1, Object[] a2) { 3900 if (a1 == null) { 3901 return a2 == null || a2.length == 0; 3902 } 3903 3904 if (a2 == null) { 3905 return a1.length == 0; 3906 } 3907 3908 if (a1.length != a2.length) { 3909 return false; 3910 } 3911 3912 for (int i = 0; i < a1.length; i++) { 3913 if (a1[i] != a2[i]) { 3914 return false; 3915 } 3916 } 3917 3918 return true; 3919 } 3920 3921 private static Field[] copyFields(Field[] arg) { 3922 Field[] out = new Field[arg.length]; 3923 ReflectionFactory fact = getReflectionFactory(); 3924 for (int i = 0; i < arg.length; i++) { 3925 out[i] = fact.copyField(arg[i]); 3926 } 3927 return out; 3928 } 3929 3930 private static Method[] copyMethods(Method[] arg) { 3931 Method[] out = new Method[arg.length]; 3932 ReflectionFactory fact = getReflectionFactory(); 3933 for (int i = 0; i < arg.length; i++) { 3934 out[i] = fact.copyMethod(arg[i]); 3935 } 3936 return out; 3937 } 3938 3939 private static <U> Constructor<U>[] copyConstructors(Constructor<U>[] arg) { 3940 Constructor<U>[] out = arg.clone(); 3941 ReflectionFactory fact = getReflectionFactory(); 3942 for (int i = 0; i < out.length; i++) { 3943 out[i] = fact.copyConstructor(out[i]); 3944 } 3945 return out; 3946 } 3947 3948 private native Field[] getDeclaredFields0(boolean publicOnly); 3949 private native Method[] getDeclaredMethods0(boolean publicOnly); 3950 private native Constructor<T>[] getDeclaredConstructors0(boolean publicOnly); 3951 private native Class<?>[] getDeclaredClasses0(); 3952 3953 /* 3954 * Returns an array containing the components of the Record attribute, 3955 * or null if the attribute is not present. 3956 * 3957 * Note that this method returns non-null array on a class with 3958 * the Record attribute even if this class is not a record. 3959 */ 3960 private native RecordComponent[] getRecordComponents0(); 3961 private native boolean isRecord0(); 3962 3963 /** 3964 * Helper method to get the method name from arguments. 3965 */ 3966 private String methodToString(String name, Class<?>[] argTypes) { 3967 return getName() + '.' + name + 3968 ((argTypes == null || argTypes.length == 0) ? 3969 "()" : 3970 Arrays.stream(argTypes) 3971 .map(c -> c == null ? "null" : c.getName()) 3972 .collect(Collectors.joining(",", "(", ")"))); 3973 } 3974 3975 /** use serialVersionUID from JDK 1.1 for interoperability */ 3976 @java.io.Serial 3977 private static final long serialVersionUID = 3206093459760846163L; 3978 3979 3980 /** 3981 * Class Class is special cased within the Serialization Stream Protocol. 3982 * 3983 * A Class instance is written initially into an ObjectOutputStream in the 3984 * following format: 3985 * <pre> 3986 * {@code TC_CLASS} ClassDescriptor 3987 * A ClassDescriptor is a special cased serialization of 3988 * a {@code java.io.ObjectStreamClass} instance. 3989 * </pre> 3990 * A new handle is generated for the initial time the class descriptor 3991 * is written into the stream. Future references to the class descriptor 3992 * are written as references to the initial class descriptor instance. 3993 * 3994 * @see java.io.ObjectStreamClass 3995 */ 3996 @java.io.Serial 3997 private static final ObjectStreamField[] serialPersistentFields = 3998 new ObjectStreamField[0]; 3999 4000 4001 /** 4002 * Returns the assertion status that would be assigned to this 4003 * class if it were to be initialized at the time this method is invoked. 4004 * If this class has had its assertion status set, the most recent 4005 * setting will be returned; otherwise, if any package default assertion 4006 * status pertains to this class, the most recent setting for the most 4007 * specific pertinent package default assertion status is returned; 4008 * otherwise, if this class is not a system class (i.e., it has a 4009 * class loader) its class loader's default assertion status is returned; 4010 * otherwise, the system class default assertion status is returned. 4011 * 4012 * @apiNote 4013 * Few programmers will have any need for this method; it is provided 4014 * for the benefit of the JDK itself. (It allows a class to determine at 4015 * the time that it is initialized whether assertions should be enabled.) 4016 * Note that this method is not guaranteed to return the actual 4017 * assertion status that was (or will be) associated with the specified 4018 * class when it was (or will be) initialized. 4019 * 4020 * @return the desired assertion status of the specified class. 4021 * @see java.lang.ClassLoader#setClassAssertionStatus 4022 * @see java.lang.ClassLoader#setPackageAssertionStatus 4023 * @see java.lang.ClassLoader#setDefaultAssertionStatus 4024 * @since 1.4 4025 */ 4026 public boolean desiredAssertionStatus() { 4027 ClassLoader loader = classLoader; 4028 // If the loader is null this is a system class, so ask the VM 4029 if (loader == null) 4030 return desiredAssertionStatus0(this); 4031 4032 // If the classloader has been initialized with the assertion 4033 // directives, ask it. Otherwise, ask the VM. 4034 synchronized(loader.assertionLock) { 4035 if (loader.classAssertionStatus != null) { 4036 return loader.desiredAssertionStatus(getName()); 4037 } 4038 } 4039 return desiredAssertionStatus0(this); 4040 } 4041 4042 // Retrieves the desired assertion status of this class from the VM 4043 private static native boolean desiredAssertionStatus0(Class<?> clazz); 4044 4045 /** 4046 * Returns true if and only if this class was declared as an enum in the 4047 * source code. 4048 * 4049 * Note that {@link java.lang.Enum} is not itself an enum class. 4050 * 4051 * Also note that if an enum constant is declared with a class body, 4052 * the class of that enum constant object is an anonymous class 4053 * and <em>not</em> the class of the declaring enum class. The 4054 * {@link Enum#getDeclaringClass} method of an enum constant can 4055 * be used to get the class of the enum class declaring the 4056 * constant. 4057 * 4058 * @return true if and only if this class was declared as an enum in the 4059 * source code 4060 * @since 1.5 4061 * @jls 8.9.1 Enum Constants 4062 */ 4063 public boolean isEnum() { 4064 // An enum must both directly extend java.lang.Enum and have 4065 // the ENUM bit set; classes for specialized enum constants 4066 // don't do the former. 4067 return (this.getModifiers() & ENUM) != 0 && 4068 this.getSuperclass() == java.lang.Enum.class; 4069 } 4070 4071 /** 4072 * Returns {@code true} if and only if this class is a record class. 4073 * 4074 * <p> The {@linkplain #getSuperclass() direct superclass} of a record 4075 * class is {@code java.lang.Record}. A record class is {@linkplain 4076 * Modifier#FINAL final}. A record class has (possibly zero) record 4077 * components; {@link #getRecordComponents()} returns a non-null but 4078 * possibly empty value for a record. 4079 * 4080 * <p> Note that class {@link Record} is not a record class and thus 4081 * invoking this method on class {@code Record} returns {@code false}. 4082 * 4083 * @return true if and only if this class is a record class, otherwise false 4084 * @jls 8.10 Record Classes 4085 * @since 16 4086 */ 4087 public boolean isRecord() { 4088 // this superclass and final modifier check is not strictly necessary 4089 // they are intrinsified and serve as a fast-path check 4090 return getSuperclass() == java.lang.Record.class && 4091 (this.getModifiers() & Modifier.FINAL) != 0 && 4092 isRecord0(); 4093 } 4094 4095 // Fetches the factory for reflective objects 4096 @SuppressWarnings("removal") 4097 private static ReflectionFactory getReflectionFactory() { 4098 var factory = reflectionFactory; 4099 if (factory != null) { 4100 return factory; 4101 } 4102 return reflectionFactory = 4103 java.security.AccessController.doPrivileged 4104 (new ReflectionFactory.GetReflectionFactoryAction()); 4105 } 4106 private static ReflectionFactory reflectionFactory; 4107 4108 /** 4109 * Returns the elements of this enum class or null if this 4110 * Class object does not represent an enum class. 4111 * 4112 * @return an array containing the values comprising the enum class 4113 * represented by this {@code Class} object in the order they're 4114 * declared, or null if this {@code Class} object does not 4115 * represent an enum class 4116 * @since 1.5 4117 * @jls 8.9.1 Enum Constants 4118 */ 4119 public T[] getEnumConstants() { 4120 T[] values = getEnumConstantsShared(); 4121 return (values != null) ? values.clone() : null; 4122 } 4123 4124 /** 4125 * Returns the elements of this enum class or null if this 4126 * Class object does not represent an enum class; 4127 * identical to getEnumConstants except that the result is 4128 * uncloned, cached, and shared by all callers. 4129 */ 4130 @SuppressWarnings("removal") 4131 T[] getEnumConstantsShared() { 4132 T[] constants = enumConstants; 4133 if (constants == null) { 4134 if (!isEnum()) return null; 4135 try { 4136 final Method values = getMethod("values"); 4137 java.security.AccessController.doPrivileged( 4138 new java.security.PrivilegedAction<>() { 4139 public Void run() { 4140 values.setAccessible(true); 4141 return null; 4142 } 4143 }); 4144 @SuppressWarnings("unchecked") 4145 T[] temporaryConstants = (T[])values.invoke(null); 4146 enumConstants = constants = temporaryConstants; 4147 } 4148 // These can happen when users concoct enum-like classes 4149 // that don't comply with the enum spec. 4150 catch (InvocationTargetException | NoSuchMethodException | 4151 IllegalAccessException | NullPointerException | 4152 ClassCastException ex) { return null; } 4153 } 4154 return constants; 4155 } 4156 private transient volatile T[] enumConstants; 4157 4158 /** 4159 * Returns a map from simple name to enum constant. This package-private 4160 * method is used internally by Enum to implement 4161 * {@code public static <T extends Enum<T>> T valueOf(Class<T>, String)} 4162 * efficiently. Note that the map is returned by this method is 4163 * created lazily on first use. Typically it won't ever get created. 4164 */ 4165 Map<String, T> enumConstantDirectory() { 4166 Map<String, T> directory = enumConstantDirectory; 4167 if (directory == null) { 4168 T[] universe = getEnumConstantsShared(); 4169 if (universe == null) 4170 throw new IllegalArgumentException( 4171 getName() + " is not an enum class"); 4172 directory = HashMap.newHashMap(universe.length); 4173 for (T constant : universe) { 4174 directory.put(((Enum<?>)constant).name(), constant); 4175 } 4176 enumConstantDirectory = directory; 4177 } 4178 return directory; 4179 } 4180 private transient volatile Map<String, T> enumConstantDirectory; 4181 4182 /** 4183 * Casts an object to the class or interface represented 4184 * by this {@code Class} object. 4185 * 4186 * @param obj the object to be cast 4187 * @return the object after casting, or null if obj is null 4188 * 4189 * @throws ClassCastException if the object is not 4190 * null and is not assignable to the type T. 4191 * 4192 * @since 1.5 4193 */ 4194 @SuppressWarnings("unchecked") 4195 @IntrinsicCandidate 4196 public T cast(Object obj) { 4197 if (obj != null && !isInstance(obj)) 4198 throw new ClassCastException(cannotCastMsg(obj)); 4199 return (T) obj; 4200 } 4201 4202 private String cannotCastMsg(Object obj) { 4203 return "Cannot cast " + obj.getClass().getName() + " to " + getName(); 4204 } 4205 4206 /** 4207 * Casts this {@code Class} object to represent a subclass of the class 4208 * represented by the specified class object. Checks that the cast 4209 * is valid, and throws a {@code ClassCastException} if it is not. If 4210 * this method succeeds, it always returns a reference to this {@code Class} object. 4211 * 4212 * <p>This method is useful when a client needs to "narrow" the type of 4213 * a {@code Class} object to pass it to an API that restricts the 4214 * {@code Class} objects that it is willing to accept. A cast would 4215 * generate a compile-time warning, as the correctness of the cast 4216 * could not be checked at runtime (because generic types are implemented 4217 * by erasure). 4218 * 4219 * @param <U> the type to cast this {@code Class} object to 4220 * @param clazz the class of the type to cast this {@code Class} object to 4221 * @return this {@code Class} object, cast to represent a subclass of 4222 * the specified class object. 4223 * @throws ClassCastException if this {@code Class} object does not 4224 * represent a subclass of the specified class (here "subclass" includes 4225 * the class itself). 4226 * @since 1.5 4227 */ 4228 @SuppressWarnings("unchecked") 4229 public <U> Class<? extends U> asSubclass(Class<U> clazz) { 4230 if (clazz.isAssignableFrom(this)) 4231 return (Class<? extends U>) this; 4232 else 4233 throw new ClassCastException(this.toString()); 4234 } 4235 4236 /** 4237 * {@inheritDoc} 4238 * <p>Note that any annotation returned by this method is a 4239 * declaration annotation. 4240 * 4241 * @throws NullPointerException {@inheritDoc} 4242 * @since 1.5 4243 */ 4244 @Override 4245 @SuppressWarnings("unchecked") 4246 public <A extends Annotation> A getAnnotation(Class<A> annotationClass) { 4247 Objects.requireNonNull(annotationClass); 4248 4249 return (A) annotationData().annotations.get(annotationClass); 4250 } 4251 4252 /** 4253 * {@inheritDoc} 4254 * @throws NullPointerException {@inheritDoc} 4255 * @since 1.5 4256 */ 4257 @Override 4258 public boolean isAnnotationPresent(Class<? extends Annotation> annotationClass) { 4259 return GenericDeclaration.super.isAnnotationPresent(annotationClass); 4260 } 4261 4262 /** 4263 * {@inheritDoc} 4264 * <p>Note that any annotations returned by this method are 4265 * declaration annotations. 4266 * 4267 * @throws NullPointerException {@inheritDoc} 4268 * @since 1.8 4269 */ 4270 @Override 4271 public <A extends Annotation> A[] getAnnotationsByType(Class<A> annotationClass) { 4272 Objects.requireNonNull(annotationClass); 4273 4274 AnnotationData annotationData = annotationData(); 4275 return AnnotationSupport.getAssociatedAnnotations(annotationData.declaredAnnotations, 4276 this, 4277 annotationClass); 4278 } 4279 4280 /** 4281 * {@inheritDoc} 4282 * <p>Note that any annotations returned by this method are 4283 * declaration annotations. 4284 * 4285 * @since 1.5 4286 */ 4287 @Override 4288 public Annotation[] getAnnotations() { 4289 return AnnotationParser.toArray(annotationData().annotations); 4290 } 4291 4292 /** 4293 * {@inheritDoc} 4294 * <p>Note that any annotation returned by this method is a 4295 * declaration annotation. 4296 * 4297 * @throws NullPointerException {@inheritDoc} 4298 * @since 1.8 4299 */ 4300 @Override 4301 @SuppressWarnings("unchecked") 4302 public <A extends Annotation> A getDeclaredAnnotation(Class<A> annotationClass) { 4303 Objects.requireNonNull(annotationClass); 4304 4305 return (A) annotationData().declaredAnnotations.get(annotationClass); 4306 } 4307 4308 /** 4309 * {@inheritDoc} 4310 * <p>Note that any annotations returned by this method are 4311 * declaration annotations. 4312 * 4313 * @throws NullPointerException {@inheritDoc} 4314 * @since 1.8 4315 */ 4316 @Override 4317 public <A extends Annotation> A[] getDeclaredAnnotationsByType(Class<A> annotationClass) { 4318 Objects.requireNonNull(annotationClass); 4319 4320 return AnnotationSupport.getDirectlyAndIndirectlyPresent(annotationData().declaredAnnotations, 4321 annotationClass); 4322 } 4323 4324 /** 4325 * {@inheritDoc} 4326 * <p>Note that any annotations returned by this method are 4327 * declaration annotations. 4328 * 4329 * @since 1.5 4330 */ 4331 @Override 4332 public Annotation[] getDeclaredAnnotations() { 4333 return AnnotationParser.toArray(annotationData().declaredAnnotations); 4334 } 4335 4336 // annotation data that might get invalidated when JVM TI RedefineClasses() is called 4337 private static class AnnotationData { 4338 final Map<Class<? extends Annotation>, Annotation> annotations; 4339 final Map<Class<? extends Annotation>, Annotation> declaredAnnotations; 4340 4341 // Value of classRedefinedCount when we created this AnnotationData instance 4342 final int redefinedCount; 4343 4344 AnnotationData(Map<Class<? extends Annotation>, Annotation> annotations, 4345 Map<Class<? extends Annotation>, Annotation> declaredAnnotations, 4346 int redefinedCount) { 4347 this.annotations = annotations; 4348 this.declaredAnnotations = declaredAnnotations; 4349 this.redefinedCount = redefinedCount; 4350 } 4351 } 4352 4353 // Annotations cache 4354 @SuppressWarnings("UnusedDeclaration") 4355 private transient volatile AnnotationData annotationData; 4356 4357 private AnnotationData annotationData() { 4358 while (true) { // retry loop 4359 AnnotationData annotationData = this.annotationData; 4360 int classRedefinedCount = this.classRedefinedCount; 4361 if (annotationData != null && 4362 annotationData.redefinedCount == classRedefinedCount) { 4363 return annotationData; 4364 } 4365 // null or stale annotationData -> optimistically create new instance 4366 AnnotationData newAnnotationData = createAnnotationData(classRedefinedCount); 4367 // try to install it 4368 if (Atomic.casAnnotationData(this, annotationData, newAnnotationData)) { 4369 // successfully installed new AnnotationData 4370 return newAnnotationData; 4371 } 4372 } 4373 } 4374 4375 private AnnotationData createAnnotationData(int classRedefinedCount) { 4376 Map<Class<? extends Annotation>, Annotation> declaredAnnotations = 4377 AnnotationParser.parseAnnotations(getRawAnnotations(), getConstantPool(), this); 4378 Class<?> superClass = getSuperclass(); 4379 Map<Class<? extends Annotation>, Annotation> annotations = null; 4380 if (superClass != null) { 4381 Map<Class<? extends Annotation>, Annotation> superAnnotations = 4382 superClass.annotationData().annotations; 4383 for (Map.Entry<Class<? extends Annotation>, Annotation> e : superAnnotations.entrySet()) { 4384 Class<? extends Annotation> annotationClass = e.getKey(); 4385 if (AnnotationType.getInstance(annotationClass).isInherited()) { 4386 if (annotations == null) { // lazy construction 4387 annotations = LinkedHashMap.newLinkedHashMap(Math.max( 4388 declaredAnnotations.size(), 4389 Math.min(12, declaredAnnotations.size() + superAnnotations.size()) 4390 ) 4391 ); 4392 } 4393 annotations.put(annotationClass, e.getValue()); 4394 } 4395 } 4396 } 4397 if (annotations == null) { 4398 // no inherited annotations -> share the Map with declaredAnnotations 4399 annotations = declaredAnnotations; 4400 } else { 4401 // at least one inherited annotation -> declared may override inherited 4402 annotations.putAll(declaredAnnotations); 4403 } 4404 return new AnnotationData(annotations, declaredAnnotations, classRedefinedCount); 4405 } 4406 4407 // Annotation interfaces cache their internal (AnnotationType) form 4408 4409 @SuppressWarnings("UnusedDeclaration") 4410 private transient volatile AnnotationType annotationType; 4411 4412 boolean casAnnotationType(AnnotationType oldType, AnnotationType newType) { 4413 return Atomic.casAnnotationType(this, oldType, newType); 4414 } 4415 4416 AnnotationType getAnnotationType() { 4417 return annotationType; 4418 } 4419 4420 Map<Class<? extends Annotation>, Annotation> getDeclaredAnnotationMap() { 4421 return annotationData().declaredAnnotations; 4422 } 4423 4424 /* Backing store of user-defined values pertaining to this class. 4425 * Maintained by the ClassValue class. 4426 */ 4427 transient ClassValue.ClassValueMap classValueMap; 4428 4429 /** 4430 * Returns an {@code AnnotatedType} object that represents the use of a 4431 * type to specify the superclass of the entity represented by this {@code 4432 * Class} object. (The <em>use</em> of type Foo to specify the superclass 4433 * in '... extends Foo' is distinct from the <em>declaration</em> of class 4434 * Foo.) 4435 * 4436 * <p> If this {@code Class} object represents a class whose declaration 4437 * does not explicitly indicate an annotated superclass, then the return 4438 * value is an {@code AnnotatedType} object representing an element with no 4439 * annotations. 4440 * 4441 * <p> If this {@code Class} represents either the {@code Object} class, an 4442 * interface type, an array type, a primitive type, or void, the return 4443 * value is {@code null}. 4444 * 4445 * @return an object representing the superclass 4446 * @since 1.8 4447 */ 4448 public AnnotatedType getAnnotatedSuperclass() { 4449 if (this == Object.class || 4450 isInterface() || 4451 isArray() || 4452 isPrimitive() || 4453 this == Void.TYPE) { 4454 return null; 4455 } 4456 4457 return TypeAnnotationParser.buildAnnotatedSuperclass(getRawTypeAnnotations(), getConstantPool(), this); 4458 } 4459 4460 /** 4461 * Returns an array of {@code AnnotatedType} objects that represent the use 4462 * of types to specify superinterfaces of the entity represented by this 4463 * {@code Class} object. (The <em>use</em> of type Foo to specify a 4464 * superinterface in '... implements Foo' is distinct from the 4465 * <em>declaration</em> of interface Foo.) 4466 * 4467 * <p> If this {@code Class} object represents a class, the return value is 4468 * an array containing objects representing the uses of interface types to 4469 * specify interfaces implemented by the class. The order of the objects in 4470 * the array corresponds to the order of the interface types used in the 4471 * 'implements' clause of the declaration of this {@code Class} object. 4472 * 4473 * <p> If this {@code Class} object represents an interface, the return 4474 * value is an array containing objects representing the uses of interface 4475 * types to specify interfaces directly extended by the interface. The 4476 * order of the objects in the array corresponds to the order of the 4477 * interface types used in the 'extends' clause of the declaration of this 4478 * {@code Class} object. 4479 * 4480 * <p> If this {@code Class} object represents a class or interface whose 4481 * declaration does not explicitly indicate any annotated superinterfaces, 4482 * the return value is an array of length 0. 4483 * 4484 * <p> If this {@code Class} object represents either the {@code Object} 4485 * class, an array type, a primitive type, or void, the return value is an 4486 * array of length 0. 4487 * 4488 * @return an array representing the superinterfaces 4489 * @since 1.8 4490 */ 4491 public AnnotatedType[] getAnnotatedInterfaces() { 4492 return TypeAnnotationParser.buildAnnotatedInterfaces(getRawTypeAnnotations(), getConstantPool(), this); 4493 } 4494 4495 private native Class<?> getNestHost0(); 4496 4497 /** 4498 * Returns the nest host of the <a href=#nest>nest</a> to which the class 4499 * or interface represented by this {@code Class} object belongs. 4500 * Every class and interface belongs to exactly one nest. 4501 * 4502 * If the nest host of this class or interface has previously 4503 * been determined, then this method returns the nest host. 4504 * If the nest host of this class or interface has 4505 * not previously been determined, then this method determines the nest 4506 * host using the algorithm of JVMS 5.4.4, and returns it. 4507 * 4508 * Often, a class or interface belongs to a nest consisting only of itself, 4509 * in which case this method returns {@code this} to indicate that the class 4510 * or interface is the nest host. 4511 * 4512 * <p>If this {@code Class} object represents a primitive type, an array type, 4513 * or {@code void}, then this method returns {@code this}, 4514 * indicating that the represented entity belongs to the nest consisting only of 4515 * itself, and is the nest host. 4516 * 4517 * @return the nest host of this class or interface 4518 * 4519 * @throws SecurityException 4520 * If the returned class is not the current class, and 4521 * if a security manager, <i>s</i>, is present and the caller's 4522 * class loader is not the same as or an ancestor of the class 4523 * loader for the returned class and invocation of {@link 4524 * SecurityManager#checkPackageAccess s.checkPackageAccess()} 4525 * denies access to the package of the returned class 4526 * @since 11 4527 * @jvms 4.7.28 The {@code NestHost} Attribute 4528 * @jvms 4.7.29 The {@code NestMembers} Attribute 4529 * @jvms 5.4.4 Access Control 4530 */ 4531 @CallerSensitive 4532 public Class<?> getNestHost() { 4533 if (isPrimitive() || isArray()) { 4534 return this; 4535 } 4536 4537 Class<?> host = getNestHost0(); 4538 if (host == this) { 4539 return this; 4540 } 4541 // returning a different class requires a security check 4542 @SuppressWarnings("removal") 4543 SecurityManager sm = System.getSecurityManager(); 4544 if (sm != null) { 4545 checkPackageAccess(sm, 4546 ClassLoader.getClassLoader(Reflection.getCallerClass()), true); 4547 } 4548 return host; 4549 } 4550 4551 /** 4552 * Determines if the given {@code Class} is a nestmate of the 4553 * class or interface represented by this {@code Class} object. 4554 * Two classes or interfaces are nestmates 4555 * if they have the same {@linkplain #getNestHost() nest host}. 4556 * 4557 * @param c the class to check 4558 * @return {@code true} if this class and {@code c} are members of 4559 * the same nest; and {@code false} otherwise. 4560 * 4561 * @since 11 4562 */ 4563 public boolean isNestmateOf(Class<?> c) { 4564 if (this == c) { 4565 return true; 4566 } 4567 if (isPrimitive() || isArray() || 4568 c.isPrimitive() || c.isArray()) { 4569 return false; 4570 } 4571 4572 return getNestHost() == c.getNestHost(); 4573 } 4574 4575 private native Class<?>[] getNestMembers0(); 4576 4577 /** 4578 * Returns an array containing {@code Class} objects representing all the 4579 * classes and interfaces that are members of the nest to which the class 4580 * or interface represented by this {@code Class} object belongs. 4581 * 4582 * First, this method obtains the {@linkplain #getNestHost() nest host}, 4583 * {@code H}, of the nest to which the class or interface represented by 4584 * this {@code Class} object belongs. The zeroth element of the returned 4585 * array is {@code H}. 4586 * 4587 * Then, for each class or interface {@code C} which is recorded by {@code H} 4588 * as being a member of its nest, this method attempts to obtain the {@code Class} 4589 * object for {@code C} (using {@linkplain #getClassLoader() the defining class 4590 * loader} of the current {@code Class} object), and then obtains the 4591 * {@linkplain #getNestHost() nest host} of the nest to which {@code C} belongs. 4592 * The classes and interfaces which are recorded by {@code H} as being members 4593 * of its nest, and for which {@code H} can be determined as their nest host, 4594 * are indicated by subsequent elements of the returned array. The order of 4595 * such elements is unspecified. Duplicates are permitted. 4596 * 4597 * <p>If this {@code Class} object represents a primitive type, an array type, 4598 * or {@code void}, then this method returns a single-element array containing 4599 * {@code this}. 4600 * 4601 * @apiNote 4602 * The returned array includes only the nest members recorded in the {@code NestMembers} 4603 * attribute, and not any hidden classes that were added to the nest via 4604 * {@link MethodHandles.Lookup#defineHiddenClass(byte[], boolean, MethodHandles.Lookup.ClassOption...) 4605 * Lookup::defineHiddenClass}. 4606 * 4607 * @return an array of all classes and interfaces in the same nest as 4608 * this class or interface 4609 * 4610 * @throws SecurityException 4611 * If any returned class is not the current class, and 4612 * if a security manager, <i>s</i>, is present and the caller's 4613 * class loader is not the same as or an ancestor of the class 4614 * loader for that returned class and invocation of {@link 4615 * SecurityManager#checkPackageAccess s.checkPackageAccess()} 4616 * denies access to the package of that returned class 4617 * 4618 * @since 11 4619 * @see #getNestHost() 4620 * @jvms 4.7.28 The {@code NestHost} Attribute 4621 * @jvms 4.7.29 The {@code NestMembers} Attribute 4622 */ 4623 @CallerSensitive 4624 public Class<?>[] getNestMembers() { 4625 if (isPrimitive() || isArray()) { 4626 return new Class<?>[] { this }; 4627 } 4628 Class<?>[] members = getNestMembers0(); 4629 // Can't actually enable this due to bootstrapping issues 4630 // assert(members.length != 1 || members[0] == this); // expected invariant from VM 4631 4632 if (members.length > 1) { 4633 // If we return anything other than the current class we need 4634 // a security check 4635 @SuppressWarnings("removal") 4636 SecurityManager sm = System.getSecurityManager(); 4637 if (sm != null) { 4638 checkPackageAccess(sm, 4639 ClassLoader.getClassLoader(Reflection.getCallerClass()), true); 4640 } 4641 } 4642 return members; 4643 } 4644 4645 /** 4646 * Returns the descriptor string of the entity (class, interface, array class, 4647 * primitive type, or {@code void}) represented by this {@code Class} object. 4648 * 4649 * <p> If this {@code Class} object represents a class or interface, 4650 * not an array class, then: 4651 * <ul> 4652 * <li> If the class or interface is not {@linkplain Class#isHidden() hidden}, 4653 * then the result is a field descriptor (JVMS {@jvms 4.3.2}) 4654 * for the class or interface. Calling 4655 * {@link ClassDesc#ofDescriptor(String) ClassDesc::ofDescriptor} 4656 * with the result descriptor string produces a {@link ClassDesc ClassDesc} 4657 * describing this class or interface. 4658 * <li> If the class or interface is {@linkplain Class#isHidden() hidden}, 4659 * then the result is a string of the form: 4660 * <blockquote> 4661 * {@code "L" +} <em>N</em> {@code + "." + <suffix> + ";"} 4662 * </blockquote> 4663 * where <em>N</em> is the {@linkplain ClassLoader##binary-name binary name} 4664 * encoded in internal form indicated by the {@code class} file passed to 4665 * {@link MethodHandles.Lookup#defineHiddenClass(byte[], boolean, MethodHandles.Lookup.ClassOption...) 4666 * Lookup::defineHiddenClass}, and {@code <suffix>} is an unqualified name. 4667 * A hidden class or interface has no {@linkplain ClassDesc nominal descriptor}. 4668 * The result string is not a type descriptor. 4669 * </ul> 4670 * 4671 * <p> If this {@code Class} object represents an array class, then 4672 * the result is a string consisting of one or more '{@code [}' characters 4673 * representing the depth of the array nesting, followed by the 4674 * descriptor string of the element type. 4675 * <ul> 4676 * <li> If the element type is not a {@linkplain Class#isHidden() hidden} class 4677 * or interface, then this array class can be described nominally. 4678 * Calling {@link ClassDesc#ofDescriptor(String) ClassDesc::ofDescriptor} 4679 * with the result descriptor string produces a {@link ClassDesc ClassDesc} 4680 * describing this array class. 4681 * <li> If the element type is a {@linkplain Class#isHidden() hidden} class or 4682 * interface, then this array class cannot be described nominally. 4683 * The result string is not a type descriptor. 4684 * </ul> 4685 * 4686 * <p> If this {@code Class} object represents a primitive type or 4687 * {@code void}, then the result is a field descriptor string which 4688 * is a one-letter code corresponding to a primitive type or {@code void} 4689 * ({@code "B", "C", "D", "F", "I", "J", "S", "Z", "V"}) (JVMS {@jvms 4.3.2}). 4690 * 4691 * @return the descriptor string for this {@code Class} object 4692 * @jvms 4.3.2 Field Descriptors 4693 * @since 12 4694 */ 4695 @Override 4696 public String descriptorString() { 4697 if (isPrimitive()) 4698 return Wrapper.forPrimitiveType(this).basicTypeString(); 4699 4700 if (isArray()) { 4701 return "[".concat(componentType.descriptorString()); 4702 } else if (isHidden()) { 4703 String name = getName(); 4704 int index = name.indexOf('/'); 4705 return new StringBuilder(name.length() + 2) 4706 .append('L') 4707 .append(name.substring(0, index).replace('.', '/')) 4708 .append('.') 4709 .append(name, index + 1, name.length()) 4710 .append(';') 4711 .toString(); 4712 } else { 4713 String name = getName().replace('.', '/'); 4714 return StringConcatHelper.concat("L", name, ";"); 4715 } 4716 } 4717 4718 /** 4719 * Returns the component type of this {@code Class}, if it describes 4720 * an array type, or {@code null} otherwise. 4721 * 4722 * @implSpec 4723 * Equivalent to {@link Class#getComponentType()}. 4724 * 4725 * @return a {@code Class} describing the component type, or {@code null} 4726 * if this {@code Class} does not describe an array type 4727 * @since 12 4728 */ 4729 @Override 4730 public Class<?> componentType() { 4731 return isArray() ? componentType : null; 4732 } 4733 4734 /** 4735 * Returns a {@code Class} for an array type whose component type 4736 * is described by this {@linkplain Class}. 4737 * 4738 * @throws UnsupportedOperationException if this component type is {@linkplain 4739 * Void#TYPE void} or if the number of dimensions of the resulting array 4740 * type would exceed 255. 4741 * @return a {@code Class} describing the array type 4742 * @jvms 4.3.2 Field Descriptors 4743 * @jvms 4.4.1 The {@code CONSTANT_Class_info} Structure 4744 * @since 12 4745 */ 4746 @Override 4747 public Class<?> arrayType() { 4748 try { 4749 return Array.newInstance(this, 0).getClass(); 4750 } catch (IllegalArgumentException iae) { 4751 throw new UnsupportedOperationException(iae); 4752 } 4753 } 4754 4755 /** 4756 * Returns a nominal descriptor for this instance, if one can be 4757 * constructed, or an empty {@link Optional} if one cannot be. 4758 * 4759 * @return An {@link Optional} containing the resulting nominal descriptor, 4760 * or an empty {@link Optional} if one cannot be constructed. 4761 * @since 12 4762 */ 4763 @Override 4764 public Optional<ClassDesc> describeConstable() { 4765 Class<?> c = isArray() ? elementType() : this; 4766 return c.isHidden() ? Optional.empty() 4767 : Optional.of(ConstantUtils.classDesc(this)); 4768 } 4769 4770 /** 4771 * Returns {@code true} if and only if the underlying class is a hidden class. 4772 * 4773 * @return {@code true} if and only if this class is a hidden class. 4774 * 4775 * @since 15 4776 * @see MethodHandles.Lookup#defineHiddenClass 4777 * @see Class##hiddenClasses Hidden Classes 4778 */ 4779 @IntrinsicCandidate 4780 public native boolean isHidden(); 4781 4782 /** 4783 * Returns an array containing {@code Class} objects representing the 4784 * direct subinterfaces or subclasses permitted to extend or 4785 * implement this class or interface if it is sealed. The order of such elements 4786 * is unspecified. The array is empty if this sealed class or interface has no 4787 * permitted subclass. If this {@code Class} object represents a primitive type, 4788 * {@code void}, an array type, or a class or interface that is not sealed, 4789 * that is {@link #isSealed()} returns {@code false}, then this method returns {@code null}. 4790 * Conversely, if {@link #isSealed()} returns {@code true}, then this method 4791 * returns a non-null value. 4792 * 4793 * For each class or interface {@code C} which is recorded as a permitted 4794 * direct subinterface or subclass of this class or interface, 4795 * this method attempts to obtain the {@code Class} 4796 * object for {@code C} (using {@linkplain #getClassLoader() the defining class 4797 * loader} of the current {@code Class} object). 4798 * The {@code Class} objects which can be obtained and which are direct 4799 * subinterfaces or subclasses of this class or interface, 4800 * are indicated by elements of the returned array. If a {@code Class} object 4801 * cannot be obtained, it is silently ignored, and not included in the result 4802 * array. 4803 * 4804 * @return an array of {@code Class} objects of the permitted subclasses of this class or interface, 4805 * or {@code null} if this class or interface is not sealed. 4806 * 4807 * @throws SecurityException 4808 * If a security manager, <i>s</i>, is present and the caller's 4809 * class loader is not the same as or an ancestor of the class 4810 * loader for that returned class and invocation of {@link 4811 * SecurityManager#checkPackageAccess s.checkPackageAccess()} 4812 * denies access to the package of any class in the returned array. 4813 * 4814 * @jls 8.1 Class Declarations 4815 * @jls 9.1 Interface Declarations 4816 * @since 17 4817 */ 4818 @CallerSensitive 4819 public Class<?>[] getPermittedSubclasses() { 4820 Class<?>[] subClasses; 4821 if (isArray() || isPrimitive() || (subClasses = getPermittedSubclasses0()) == null) { 4822 return null; 4823 } 4824 if (subClasses.length > 0) { 4825 if (Arrays.stream(subClasses).anyMatch(c -> !isDirectSubType(c))) { 4826 subClasses = Arrays.stream(subClasses) 4827 .filter(this::isDirectSubType) 4828 .toArray(s -> new Class<?>[s]); 4829 } 4830 } 4831 if (subClasses.length > 0) { 4832 // If we return some classes we need a security check: 4833 @SuppressWarnings("removal") 4834 SecurityManager sm = System.getSecurityManager(); 4835 if (sm != null) { 4836 checkPackageAccessForPermittedSubclasses(sm, 4837 ClassLoader.getClassLoader(Reflection.getCallerClass()), 4838 subClasses); 4839 } 4840 } 4841 return subClasses; 4842 } 4843 4844 private boolean isDirectSubType(Class<?> c) { 4845 if (isInterface()) { 4846 for (Class<?> i : c.getInterfaces(/* cloneArray */ false)) { 4847 if (i == this) { 4848 return true; 4849 } 4850 } 4851 } else { 4852 return c.getSuperclass() == this; 4853 } 4854 return false; 4855 } 4856 4857 /** 4858 * Returns {@code true} if and only if this {@code Class} object represents 4859 * a sealed class or interface. If this {@code Class} object represents a 4860 * primitive type, {@code void}, or an array type, this method returns 4861 * {@code false}. A sealed class or interface has (possibly zero) permitted 4862 * subclasses; {@link #getPermittedSubclasses()} returns a non-null but 4863 * possibly empty value for a sealed class or interface. 4864 * 4865 * @return {@code true} if and only if this {@code Class} object represents 4866 * a sealed class or interface. 4867 * 4868 * @jls 8.1 Class Declarations 4869 * @jls 9.1 Interface Declarations 4870 * @since 17 4871 */ 4872 public boolean isSealed() { 4873 if (isArray() || isPrimitive()) { 4874 return false; 4875 } 4876 return getPermittedSubclasses() != null; 4877 } 4878 4879 private native Class<?>[] getPermittedSubclasses0(); 4880 4881 /* 4882 * Return the class's major and minor class file version packed into an int. 4883 * The high order 16 bits contain the class's minor version. The low order 4884 * 16 bits contain the class's major version. 4885 * 4886 * If the class is an array type then the class file version of its element 4887 * type is returned. If the class is a primitive type then the latest class 4888 * file major version is returned and zero is returned for the minor version. 4889 */ 4890 /* package-private */ 4891 int getClassFileVersion() { 4892 Class<?> c = isArray() ? elementType() : this; 4893 return c.getClassFileVersion0(); 4894 } 4895 4896 private native int getClassFileVersion0(); 4897 4898 /* 4899 * Return the access flags as they were in the class's bytecode, including 4900 * the original setting of ACC_SUPER. 4901 * 4902 * If the class is an array type then the access flags of the element type is 4903 * returned. If the class is a primitive then ACC_ABSTRACT | ACC_FINAL | ACC_PUBLIC. 4904 */ 4905 private int getClassAccessFlagsRaw() { 4906 Class<?> c = isArray() ? elementType() : this; 4907 return c.getClassAccessFlagsRaw0(); 4908 } 4909 4910 private native int getClassAccessFlagsRaw0(); 4911 }