1 /* 2 * Copyright (c) 1994, 2018, 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 package java.lang; 26 27 import java.io.BufferedInputStream; 28 import java.io.BufferedOutputStream; 29 import java.io.Console; 30 import java.io.FileDescriptor; 31 import java.io.FileInputStream; 32 import java.io.FileOutputStream; 33 import java.io.IOException; 34 import java.io.InputStream; 35 import java.io.PrintStream; 36 import java.io.UnsupportedEncodingException; 37 import java.lang.annotation.Annotation; 38 import java.lang.module.ModuleDescriptor; 39 import java.lang.reflect.Constructor; 40 import java.lang.reflect.Executable; 41 import java.lang.reflect.Method; 42 import java.lang.reflect.Modifier; 43 import java.net.URI; 44 import java.nio.charset.CharacterCodingException; 45 import java.security.AccessControlContext; 46 import java.security.ProtectionDomain; 47 import java.security.AccessController; 48 import java.security.PrivilegedAction; 49 import java.nio.channels.Channel; 50 import java.nio.channels.spi.SelectorProvider; 51 import java.nio.charset.Charset; 52 import java.util.Iterator; 53 import java.util.List; 54 import java.util.Map; 55 import java.util.Objects; 56 import java.util.Properties; 57 import java.util.PropertyPermission; 58 import java.util.ResourceBundle; 59 import java.util.function.Supplier; 60 import java.util.concurrent.ConcurrentHashMap; 61 import java.util.stream.Stream; 62 63 import jdk.internal.util.StaticProperty; 64 import jdk.internal.module.ModuleBootstrap; 65 import jdk.internal.module.ServicesCatalog; 66 import jdk.internal.reflect.CallerSensitive; 67 import jdk.internal.reflect.Reflection; 68 import jdk.internal.HotSpotIntrinsicCandidate; 69 import jdk.internal.access.JavaLangAccess; 70 import jdk.internal.access.SharedSecrets; 71 import jdk.internal.misc.VM; 72 import jdk.internal.logger.LoggerFinderLoader; 73 import jdk.internal.logger.LazyLoggers; 74 import jdk.internal.logger.LocalizedLoggerWrapper; 75 import jdk.internal.vm.annotation.Stable; 76 import sun.reflect.annotation.AnnotationType; 77 import sun.nio.ch.Interruptible; 78 import sun.security.util.SecurityConstants; 79 80 /** 81 * The {@code System} class contains several useful class fields 82 * and methods. It cannot be instantiated. 83 * 84 * Among the facilities provided by the {@code System} class 85 * are standard input, standard output, and error output streams; 86 * access to externally defined properties and environment 87 * variables; a means of loading files and libraries; and a utility 88 * method for quickly copying a portion of an array. 89 * 90 * @since 1.0 91 */ 92 public final class System { 93 /* Register the natives via the static initializer. 94 * 95 * VM will invoke the initializeSystemClass method to complete 96 * the initialization for this class separated from clinit. 97 * Note that to use properties set by the VM, see the constraints 98 * described in the initializeSystemClass method. 99 */ 100 private static native void registerNatives(); 101 static { 102 registerNatives(); 103 } 104 105 /** Don't let anyone instantiate this class */ 106 private System() { 107 } 108 109 /** 110 * The "standard" input stream. This stream is already 111 * open and ready to supply input data. Typically this stream 112 * corresponds to keyboard input or another input source specified by 113 * the host environment or user. 114 */ 115 public static final InputStream in = null; 116 117 /** 118 * The "standard" output stream. This stream is already 119 * open and ready to accept output data. Typically this stream 120 * corresponds to display output or another output destination 121 * specified by the host environment or user. 122 * <p> 123 * For simple stand-alone Java applications, a typical way to write 124 * a line of output data is: 125 * <blockquote><pre> 126 * System.out.println(data) 127 * </pre></blockquote> 128 * <p> 129 * See the {@code println} methods in class {@code PrintStream}. 130 * 131 * @see java.io.PrintStream#println() 132 * @see java.io.PrintStream#println(boolean) 133 * @see java.io.PrintStream#println(char) 134 * @see java.io.PrintStream#println(char[]) 135 * @see java.io.PrintStream#println(double) 136 * @see java.io.PrintStream#println(float) 137 * @see java.io.PrintStream#println(int) 138 * @see java.io.PrintStream#println(long) 139 * @see java.io.PrintStream#println(java.lang.Object) 140 * @see java.io.PrintStream#println(java.lang.String) 141 */ 142 public static final PrintStream out = null; 143 144 /** 145 * The "standard" error output stream. This stream is already 146 * open and ready to accept output data. 147 * <p> 148 * Typically this stream corresponds to display output or another 149 * output destination specified by the host environment or user. By 150 * convention, this output stream is used to display error messages 151 * or other information that should come to the immediate attention 152 * of a user even if the principal output stream, the value of the 153 * variable {@code out}, has been redirected to a file or other 154 * destination that is typically not continuously monitored. 155 */ 156 public static final PrintStream err = null; 157 158 // indicates if a security manager is possible 159 private static final int NEVER = 1; 160 private static final int MAYBE = 2; 161 private static @Stable int allowSecurityManager; 162 163 // current security manager 164 private static volatile SecurityManager security; // read by VM 165 166 // return true if a security manager is allowed 167 private static boolean allowSecurityManager() { 168 return (allowSecurityManager != NEVER); 169 } 170 171 /** 172 * Reassigns the "standard" input stream. 173 * 174 * First, if there is a security manager, its {@code checkPermission} 175 * method is called with a {@code RuntimePermission("setIO")} permission 176 * to see if it's ok to reassign the "standard" input stream. 177 * 178 * @param in the new standard input stream. 179 * 180 * @throws SecurityException 181 * if a security manager exists and its 182 * {@code checkPermission} method doesn't allow 183 * reassigning of the standard input stream. 184 * 185 * @see SecurityManager#checkPermission 186 * @see java.lang.RuntimePermission 187 * 188 * @since 1.1 189 */ 190 public static void setIn(InputStream in) { 191 checkIO(); 192 setIn0(in); 193 } 194 195 /** 196 * Reassigns the "standard" output stream. 197 * 198 * First, if there is a security manager, its {@code checkPermission} 199 * method is called with a {@code RuntimePermission("setIO")} permission 200 * to see if it's ok to reassign the "standard" output stream. 201 * 202 * @param out the new standard output stream 203 * 204 * @throws SecurityException 205 * if a security manager exists and its 206 * {@code checkPermission} method doesn't allow 207 * reassigning of the standard output stream. 208 * 209 * @see SecurityManager#checkPermission 210 * @see java.lang.RuntimePermission 211 * 212 * @since 1.1 213 */ 214 public static void setOut(PrintStream out) { 215 checkIO(); 216 setOut0(out); 217 } 218 219 /** 220 * Reassigns the "standard" error output stream. 221 * 222 * First, if there is a security manager, its {@code checkPermission} 223 * method is called with a {@code RuntimePermission("setIO")} permission 224 * to see if it's ok to reassign the "standard" error output stream. 225 * 226 * @param err the new standard error output stream. 227 * 228 * @throws SecurityException 229 * if a security manager exists and its 230 * {@code checkPermission} method doesn't allow 231 * reassigning of the standard error output stream. 232 * 233 * @see SecurityManager#checkPermission 234 * @see java.lang.RuntimePermission 235 * 236 * @since 1.1 237 */ 238 public static void setErr(PrintStream err) { 239 checkIO(); 240 setErr0(err); 241 } 242 243 private static volatile Console cons; 244 245 /** 246 * Returns the unique {@link java.io.Console Console} object associated 247 * with the current Java virtual machine, if any. 248 * 249 * @return The system console, if any, otherwise {@code null}. 250 * 251 * @since 1.6 252 */ 253 public static Console console() { 254 Console c; 255 if ((c = cons) == null) { 256 synchronized (System.class) { 257 if ((c = cons) == null) { 258 cons = c = SharedSecrets.getJavaIOAccess().console(); 259 } 260 } 261 } 262 return c; 263 } 264 265 /** 266 * Returns the channel inherited from the entity that created this 267 * Java virtual machine. 268 * 269 * This method returns the channel obtained by invoking the 270 * {@link java.nio.channels.spi.SelectorProvider#inheritedChannel 271 * inheritedChannel} method of the system-wide default 272 * {@link java.nio.channels.spi.SelectorProvider} object. 273 * 274 * <p> In addition to the network-oriented channels described in 275 * {@link java.nio.channels.spi.SelectorProvider#inheritedChannel 276 * inheritedChannel}, this method may return other kinds of 277 * channels in the future. 278 * 279 * @return The inherited channel, if any, otherwise {@code null}. 280 * 281 * @throws IOException 282 * If an I/O error occurs 283 * 284 * @throws SecurityException 285 * If a security manager is present and it does not 286 * permit access to the channel. 287 * 288 * @since 1.5 289 */ 290 public static Channel inheritedChannel() throws IOException { 291 return SelectorProvider.provider().inheritedChannel(); 292 } 293 294 private static void checkIO() { 295 SecurityManager sm = getSecurityManager(); 296 if (sm != null) { 297 sm.checkPermission(new RuntimePermission("setIO")); 298 } 299 } 300 301 private static native void setIn0(InputStream in); 302 private static native void setOut0(PrintStream out); 303 private static native void setErr0(PrintStream err); 304 305 /** 306 * Sets the system-wide security manager. 307 * 308 * If there is a security manager already installed, this method first 309 * calls the security manager's {@code checkPermission} method 310 * with a {@code RuntimePermission("setSecurityManager")} 311 * permission to ensure it's ok to replace the existing 312 * security manager. 313 * This may result in throwing a {@code SecurityException}. 314 * 315 * <p> Otherwise, the argument is established as the current 316 * security manager. If the argument is {@code null} and no 317 * security manager has been established, then no action is taken and 318 * the method simply returns. 319 * 320 * @implNote In the JDK implementation, if the Java virtual machine is 321 * started with the system property {@code java.security.manager} set to 322 * the special token "{@code disallow}" then the {@code setSecurityManager} 323 * method cannot be used to set a security manager. 324 * 325 * @param sm the security manager or {@code null} 326 * @throws SecurityException 327 * if the security manager has already been set and its {@code 328 * checkPermission} method doesn't allow it to be replaced 329 * @throws UnsupportedOperationException 330 * if {@code sm} is non-null and a security manager is not allowed 331 * to be set dynamically 332 * @see #getSecurityManager 333 * @see SecurityManager#checkPermission 334 * @see java.lang.RuntimePermission 335 */ 336 public static void setSecurityManager(SecurityManager sm) { 337 if (allowSecurityManager()) { 338 if (security == null) { 339 // ensure image reader is initialized 340 Object.class.getResource("java/lang/ANY"); 341 } 342 if (sm != null) { 343 try { 344 // pre-populates the SecurityManager.packageAccess cache 345 // to avoid recursive permission checking issues with custom 346 // SecurityManager implementations 347 sm.checkPackageAccess("java.lang"); 348 } catch (Exception e) { 349 // no-op 350 } 351 } 352 setSecurityManager0(sm); 353 } else { 354 // security manager not allowed 355 if (sm != null) { 356 throw new UnsupportedOperationException( 357 "Runtime configured to disallow security manager"); 358 } 359 } 360 } 361 362 private static synchronized 363 void setSecurityManager0(final SecurityManager s) { 364 SecurityManager sm = getSecurityManager(); 365 if (sm != null) { 366 // ask the currently installed security manager if we 367 // can replace it. 368 sm.checkPermission(new RuntimePermission("setSecurityManager")); 369 } 370 371 if ((s != null) && (s.getClass().getClassLoader() != null)) { 372 // New security manager class is not on bootstrap classpath. 373 // Force policy to get initialized before we install the new 374 // security manager, in order to prevent infinite loops when 375 // trying to initialize the policy (which usually involves 376 // accessing some security and/or system properties, which in turn 377 // calls the installed security manager's checkPermission method 378 // which will loop infinitely if there is a non-system class 379 // (in this case: the new security manager class) on the stack). 380 AccessController.doPrivileged(new PrivilegedAction<>() { 381 public Object run() { 382 s.getClass().getProtectionDomain().implies 383 (SecurityConstants.ALL_PERMISSION); 384 return null; 385 } 386 }); 387 } 388 389 security = s; 390 } 391 392 /** 393 * Gets the system-wide security manager. 394 * 395 * @return if a security manager has already been established for the 396 * current application, then that security manager is returned; 397 * otherwise, {@code null} is returned. 398 * @see #setSecurityManager 399 */ 400 public static SecurityManager getSecurityManager() { 401 if (allowSecurityManager()) { 402 return security; 403 } else { 404 return null; 405 } 406 } 407 408 /** 409 * Returns the current time in milliseconds. Note that 410 * while the unit of time of the return value is a millisecond, 411 * the granularity of the value depends on the underlying 412 * operating system and may be larger. For example, many 413 * operating systems measure time in units of tens of 414 * milliseconds. 415 * 416 * <p> See the description of the class {@code Date} for 417 * a discussion of slight discrepancies that may arise between 418 * "computer time" and coordinated universal time (UTC). 419 * 420 * @return the difference, measured in milliseconds, between 421 * the current time and midnight, January 1, 1970 UTC. 422 * @see java.util.Date 423 */ 424 @HotSpotIntrinsicCandidate 425 public static native long currentTimeMillis(); 426 427 /** 428 * Returns the current value of the running Java Virtual Machine's 429 * high-resolution time source, in nanoseconds. 430 * 431 * This method can only be used to measure elapsed time and is 432 * not related to any other notion of system or wall-clock time. 433 * The value returned represents nanoseconds since some fixed but 434 * arbitrary <i>origin</i> time (perhaps in the future, so values 435 * may be negative). The same origin is used by all invocations of 436 * this method in an instance of a Java virtual machine; other 437 * virtual machine instances are likely to use a different origin. 438 * 439 * <p>This method provides nanosecond precision, but not necessarily 440 * nanosecond resolution (that is, how frequently the value changes) 441 * - no guarantees are made except that the resolution is at least as 442 * good as that of {@link #currentTimeMillis()}. 443 * 444 * <p>Differences in successive calls that span greater than 445 * approximately 292 years (2<sup>63</sup> nanoseconds) will not 446 * correctly compute elapsed time due to numerical overflow. 447 * 448 * <p>The values returned by this method become meaningful only when 449 * the difference between two such values, obtained within the same 450 * instance of a Java virtual machine, is computed. 451 * 452 * <p>For example, to measure how long some code takes to execute: 453 * <pre> {@code 454 * long startTime = System.nanoTime(); 455 * // ... the code being measured ... 456 * long elapsedNanos = System.nanoTime() - startTime;}</pre> 457 * 458 * <p>To compare elapsed time against a timeout, use <pre> {@code 459 * if (System.nanoTime() - startTime >= timeoutNanos) ...}</pre> 460 * instead of <pre> {@code 461 * if (System.nanoTime() >= startTime + timeoutNanos) ...}</pre> 462 * because of the possibility of numerical overflow. 463 * 464 * @return the current value of the running Java Virtual Machine's 465 * high-resolution time source, in nanoseconds 466 * @since 1.5 467 */ 468 @HotSpotIntrinsicCandidate 469 public static native long nanoTime(); 470 471 /** 472 * Copies an array from the specified source array, beginning at the 473 * specified position, to the specified position of the destination array. 474 * A subsequence of array components are copied from the source 475 * array referenced by {@code src} to the destination array 476 * referenced by {@code dest}. The number of components copied is 477 * equal to the {@code length} argument. The components at 478 * positions {@code srcPos} through 479 * {@code srcPos+length-1} in the source array are copied into 480 * positions {@code destPos} through 481 * {@code destPos+length-1}, respectively, of the destination 482 * array. 483 * <p> 484 * If the {@code src} and {@code dest} arguments refer to the 485 * same array object, then the copying is performed as if the 486 * components at positions {@code srcPos} through 487 * {@code srcPos+length-1} were first copied to a temporary 488 * array with {@code length} components and then the contents of 489 * the temporary array were copied into positions 490 * {@code destPos} through {@code destPos+length-1} of the 491 * destination array. 492 * <p> 493 * If {@code dest} is {@code null}, then a 494 * {@code NullPointerException} is thrown. 495 * <p> 496 * If {@code src} is {@code null}, then a 497 * {@code NullPointerException} is thrown and the destination 498 * array is not modified. 499 * <p> 500 * Otherwise, if any of the following is true, an 501 * {@code ArrayStoreException} is thrown and the destination is 502 * not modified: 503 * <ul> 504 * <li>The {@code src} argument refers to an object that is not an 505 * array. 506 * <li>The {@code dest} argument refers to an object that is not an 507 * array. 508 * <li>The {@code src} argument and {@code dest} argument refer 509 * to arrays whose component types are different primitive types. 510 * <li>The {@code src} argument refers to an array with a primitive 511 * component type and the {@code dest} argument refers to an array 512 * with a reference component type. 513 * <li>The {@code src} argument refers to an array with a reference 514 * component type and the {@code dest} argument refers to an array 515 * with a primitive component type. 516 * </ul> 517 * <p> 518 * Otherwise, if any of the following is true, an 519 * {@code IndexOutOfBoundsException} is 520 * thrown and the destination is not modified: 521 * <ul> 522 * <li>The {@code srcPos} argument is negative. 523 * <li>The {@code destPos} argument is negative. 524 * <li>The {@code length} argument is negative. 525 * <li>{@code srcPos+length} is greater than 526 * {@code src.length}, the length of the source array. 527 * <li>{@code destPos+length} is greater than 528 * {@code dest.length}, the length of the destination array. 529 * </ul> 530 * <p> 531 * Otherwise, if any actual component of the source array from 532 * position {@code srcPos} through 533 * {@code srcPos+length-1} cannot be converted to the component 534 * type of the destination array by assignment conversion, an 535 * {@code ArrayStoreException} is thrown. In this case, let 536 * <b><i>k</i></b> be the smallest nonnegative integer less than 537 * length such that {@code src[srcPos+}<i>k</i>{@code ]} 538 * cannot be converted to the component type of the destination 539 * array; when the exception is thrown, source array components from 540 * positions {@code srcPos} through 541 * {@code srcPos+}<i>k</i>{@code -1} 542 * will already have been copied to destination array positions 543 * {@code destPos} through 544 * {@code destPos+}<i>k</I>{@code -1} and no other 545 * positions of the destination array will have been modified. 546 * (Because of the restrictions already itemized, this 547 * paragraph effectively applies only to the situation where both 548 * arrays have component types that are reference types.) 549 * 550 * @param src the source array. 551 * @param srcPos starting position in the source array. 552 * @param dest the destination array. 553 * @param destPos starting position in the destination data. 554 * @param length the number of array elements to be copied. 555 * @throws IndexOutOfBoundsException if copying would cause 556 * access of data outside array bounds. 557 * @throws ArrayStoreException if an element in the {@code src} 558 * array could not be stored into the {@code dest} array 559 * because of a type mismatch. 560 * @throws NullPointerException if either {@code src} or 561 * {@code dest} is {@code null}. 562 */ 563 @HotSpotIntrinsicCandidate 564 public static native void arraycopy(Object src, int srcPos, 565 Object dest, int destPos, 566 int length); 567 568 /** 569 * Returns the same hash code for the given object as 570 * would be returned by the default method hashCode(), 571 * whether or not the given object's class overrides 572 * hashCode(). 573 * The hash code for the null reference is zero. 574 * 575 * @param x object for which the hashCode is to be calculated 576 * @return the hashCode 577 * @since 1.1 578 * @see Object#hashCode 579 * @see java.util.Objects#hashCode(Object) 580 */ 581 @HotSpotIntrinsicCandidate 582 public static native int identityHashCode(Object x); 583 584 /** 585 * System properties. The following properties are guaranteed to be defined: 586 * <dl> 587 * <dt>java.version <dd>Java version number 588 * <dt>java.version.date <dd>Java version date 589 * <dt>java.vendor <dd>Java vendor specific string 590 * <dt>java.vendor.url <dd>Java vendor URL 591 * <dt>java.vendor.version <dd>Java vendor version 592 * <dt>java.home <dd>Java installation directory 593 * <dt>java.class.version <dd>Java class version number 594 * <dt>java.class.path <dd>Java classpath 595 * <dt>os.name <dd>Operating System Name 596 * <dt>os.arch <dd>Operating System Architecture 597 * <dt>os.version <dd>Operating System Version 598 * <dt>file.separator <dd>File separator ("/" on Unix) 599 * <dt>path.separator <dd>Path separator (":" on Unix) 600 * <dt>line.separator <dd>Line separator ("\n" on Unix) 601 * <dt>user.name <dd>User account name 602 * <dt>user.home <dd>User home directory 603 * <dt>user.dir <dd>User's current working directory 604 * </dl> 605 */ 606 607 private static Properties props; 608 private static native Properties initProperties(Properties props); 609 610 /** 611 * Determines the current system properties. 612 * 613 * First, if there is a security manager, its 614 * {@code checkPropertiesAccess} method is called with no 615 * arguments. This may result in a security exception. 616 * <p> 617 * The current set of system properties for use by the 618 * {@link #getProperty(String)} method is returned as a 619 * {@code Properties} object. If there is no current set of 620 * system properties, a set of system properties is first created and 621 * initialized. This set of system properties always includes values 622 * for the following keys: 623 * <table class="striped" style="text-align:left"> 624 * <caption style="display:none">Shows property keys and associated values</caption> 625 * <thead> 626 * <tr><th scope="col">Key</th> 627 * <th scope="col">Description of Associated Value</th></tr> 628 * </thead> 629 * <tbody> 630 * <tr><th scope="row">{@code java.version}</th> 631 * <td>Java Runtime Environment version, which may be interpreted 632 * as a {@link Runtime.Version}</td></tr> 633 * <tr><th scope="row">{@code java.version.date}</th> 634 * <td>Java Runtime Environment version date, in ISO-8601 YYYY-MM-DD 635 * format, which may be interpreted as a {@link 636 * java.time.LocalDate}</td></tr> 637 * <tr><th scope="row">{@code java.vendor}</th> 638 * <td>Java Runtime Environment vendor</td></tr> 639 * <tr><th scope="row">{@code java.vendor.url}</th> 640 * <td>Java vendor URL</td></tr> 641 * <tr><th scope="row">{@code java.vendor.version}</th> 642 * <td>Java vendor version</td></tr> 643 * <tr><th scope="row">{@code java.home}</th> 644 * <td>Java installation directory</td></tr> 645 * <tr><th scope="row">{@code java.vm.specification.version}</th> 646 * <td>Java Virtual Machine specification version, whose value is the 647 * {@linkplain Runtime.Version#feature feature} element of the 648 * {@linkplain Runtime#version() runtime version}</td></tr> 649 * <tr><th scope="row">{@code java.vm.specification.vendor}</th> 650 * <td>Java Virtual Machine specification vendor</td></tr> 651 * <tr><th scope="row">{@code java.vm.specification.name}</th> 652 * <td>Java Virtual Machine specification name</td></tr> 653 * <tr><th scope="row">{@code java.vm.version}</th> 654 * <td>Java Virtual Machine implementation version which may be 655 * interpreted as a {@link Runtime.Version}</td></tr> 656 * <tr><th scope="row">{@code java.vm.vendor}</th> 657 * <td>Java Virtual Machine implementation vendor</td></tr> 658 * <tr><th scope="row">{@code java.vm.name}</th> 659 * <td>Java Virtual Machine implementation name</td></tr> 660 * <tr><th scope="row">{@code java.specification.version}</th> 661 * <td>Java Runtime Environment specification version, whose value is 662 * the {@linkplain Runtime.Version#feature feature} element of the 663 * {@linkplain Runtime#version() runtime version}</td></tr> 664 * <tr><th scope="row">{@code java.specification.vendor}</th> 665 * <td>Java Runtime Environment specification vendor</td></tr> 666 * <tr><th scope="row">{@code java.specification.name}</th> 667 * <td>Java Runtime Environment specification name</td></tr> 668 * <tr><th scope="row">{@code java.class.version}</th> 669 * <td>Java class format version number</td></tr> 670 * <tr><th scope="row">{@code java.class.path}</th> 671 * <td>Java class path (refer to 672 * {@link ClassLoader#getSystemClassLoader()} for details)</td></tr> 673 * <tr><th scope="row">{@code java.library.path}</th> 674 * <td>List of paths to search when loading libraries</td></tr> 675 * <tr><th scope="row">{@code java.io.tmpdir}</th> 676 * <td>Default temp file path</td></tr> 677 * <tr><th scope="row">{@code java.compiler}</th> 678 * <td>Name of JIT compiler to use</td></tr> 679 * <tr><th scope="row">{@code os.name}</th> 680 * <td>Operating system name</td></tr> 681 * <tr><th scope="row">{@code os.arch}</th> 682 * <td>Operating system architecture</td></tr> 683 * <tr><th scope="row">{@code os.version}</th> 684 * <td>Operating system version</td></tr> 685 * <tr><th scope="row">{@code file.separator}</th> 686 * <td>File separator ("/" on UNIX)</td></tr> 687 * <tr><th scope="row">{@code path.separator}</th> 688 * <td>Path separator (":" on UNIX)</td></tr> 689 * <tr><th scope="row">{@code line.separator}</th> 690 * <td>Line separator ("\n" on UNIX)</td></tr> 691 * <tr><th scope="row">{@code user.name}</th> 692 * <td>User's account name</td></tr> 693 * <tr><th scope="row">{@code user.home}</th> 694 * <td>User's home directory</td></tr> 695 * <tr><th scope="row">{@code user.dir}</th> 696 * <td>User's current working directory</td></tr> 697 * </tbody> 698 * </table> 699 * <p> 700 * Multiple paths in a system property value are separated by the path 701 * separator character of the platform. 702 * <p> 703 * Note that even if the security manager does not permit the 704 * {@code getProperties} operation, it may choose to permit the 705 * {@link #getProperty(String)} operation. 706 * 707 * @apiNote 708 * <strong>Changing a standard system property may have unpredictable results 709 * unless otherwise specified.</strong> 710 * Property values may be cached during initialization or on first use. 711 * Setting a standard property after initialization using {@link #getProperties()}, 712 * {@link #setProperties(Properties)}, {@link #setProperty(String, String)}, or 713 * {@link #clearProperty(String)} may not have the desired effect. 714 * 715 * @implNote 716 * In addition to the standard system properties, the system 717 * properties may include the following keys: 718 * <table class="striped"> 719 * <caption style="display:none">Shows property keys and associated values</caption> 720 * <thead> 721 * <tr><th scope="col">Key</th> 722 * <th scope="col">Description of Associated Value</th></tr> 723 * </thead> 724 * <tbody> 725 * <tr><th scope="row">{@code jdk.module.path}</th> 726 * <td>The application module path</td></tr> 727 * <tr><th scope="row">{@code jdk.module.upgrade.path}</th> 728 * <td>The upgrade module path</td></tr> 729 * <tr><th scope="row">{@code jdk.module.main}</th> 730 * <td>The module name of the initial/main module</td></tr> 731 * <tr><th scope="row">{@code jdk.module.main.class}</th> 732 * <td>The main class name of the initial module</td></tr> 733 * </tbody> 734 * </table> 735 * 736 * @return the system properties 737 * @throws SecurityException if a security manager exists and its 738 * {@code checkPropertiesAccess} method doesn't allow access 739 * to the system properties. 740 * @see #setProperties 741 * @see java.lang.SecurityException 742 * @see java.lang.SecurityManager#checkPropertiesAccess() 743 * @see java.util.Properties 744 */ 745 public static Properties getProperties() { 746 SecurityManager sm = getSecurityManager(); 747 if (sm != null) { 748 sm.checkPropertiesAccess(); 749 } 750 751 return props; 752 } 753 754 /** 755 * Returns the system-dependent line separator string. It always 756 * returns the same value - the initial value of the {@linkplain 757 * #getProperty(String) system property} {@code line.separator}. 758 * 759 * <p>On UNIX systems, it returns {@code "\n"}; on Microsoft 760 * Windows systems it returns {@code "\r\n"}. 761 * 762 * @return the system-dependent line separator string 763 * @since 1.7 764 */ 765 public static String lineSeparator() { 766 return lineSeparator; 767 } 768 769 private static String lineSeparator; 770 771 /** 772 * Sets the system properties to the {@code Properties} argument. 773 * 774 * First, if there is a security manager, its 775 * {@code checkPropertiesAccess} method is called with no 776 * arguments. This may result in a security exception. 777 * <p> 778 * The argument becomes the current set of system properties for use 779 * by the {@link #getProperty(String)} method. If the argument is 780 * {@code null}, then the current set of system properties is 781 * forgotten. 782 * 783 * @apiNote 784 * <strong>Changing a standard system property may have unpredictable results 785 * unless otherwise specified</strong>. 786 * See {@linkplain #getProperties getProperties} for details. 787 * 788 * @param props the new system properties. 789 * @throws SecurityException if a security manager exists and its 790 * {@code checkPropertiesAccess} method doesn't allow access 791 * to the system properties. 792 * @see #getProperties 793 * @see java.util.Properties 794 * @see java.lang.SecurityException 795 * @see java.lang.SecurityManager#checkPropertiesAccess() 796 */ 797 public static void setProperties(Properties props) { 798 SecurityManager sm = getSecurityManager(); 799 if (sm != null) { 800 sm.checkPropertiesAccess(); 801 } 802 if (props == null) { 803 props = new Properties(); 804 initProperties(props); 805 VersionProps.init(props); 806 } 807 System.props = props; 808 } 809 810 /** 811 * Gets the system property indicated by the specified key. 812 * 813 * First, if there is a security manager, its 814 * {@code checkPropertyAccess} method is called with the key as 815 * its argument. This may result in a SecurityException. 816 * <p> 817 * If there is no current set of system properties, a set of system 818 * properties is first created and initialized in the same manner as 819 * for the {@code getProperties} method. 820 * 821 * @apiNote 822 * <strong>Changing a standard system property may have unpredictable results 823 * unless otherwise specified</strong>. 824 * See {@linkplain #getProperties getProperties} for details. 825 * 826 * @param key the name of the system property. 827 * @return the string value of the system property, 828 * or {@code null} if there is no property with that key. 829 * 830 * @throws SecurityException if a security manager exists and its 831 * {@code checkPropertyAccess} method doesn't allow 832 * access to the specified system property. 833 * @throws NullPointerException if {@code key} is {@code null}. 834 * @throws IllegalArgumentException if {@code key} is empty. 835 * @see #setProperty 836 * @see java.lang.SecurityException 837 * @see java.lang.SecurityManager#checkPropertyAccess(java.lang.String) 838 * @see java.lang.System#getProperties() 839 */ 840 public static String getProperty(String key) { 841 checkKey(key); 842 SecurityManager sm = getSecurityManager(); 843 if (sm != null) { 844 sm.checkPropertyAccess(key); 845 } 846 847 return props.getProperty(key); 848 } 849 850 /** 851 * Gets the system property indicated by the specified key. 852 * 853 * First, if there is a security manager, its 854 * {@code checkPropertyAccess} method is called with the 855 * {@code key} as its argument. 856 * <p> 857 * If there is no current set of system properties, a set of system 858 * properties is first created and initialized in the same manner as 859 * for the {@code getProperties} method. 860 * 861 * @param key the name of the system property. 862 * @param def a default value. 863 * @return the string value of the system property, 864 * or the default value if there is no property with that key. 865 * 866 * @throws SecurityException if a security manager exists and its 867 * {@code checkPropertyAccess} method doesn't allow 868 * access to the specified system property. 869 * @throws NullPointerException if {@code key} is {@code null}. 870 * @throws IllegalArgumentException if {@code key} is empty. 871 * @see #setProperty 872 * @see java.lang.SecurityManager#checkPropertyAccess(java.lang.String) 873 * @see java.lang.System#getProperties() 874 */ 875 public static String getProperty(String key, String def) { 876 checkKey(key); 877 SecurityManager sm = getSecurityManager(); 878 if (sm != null) { 879 sm.checkPropertyAccess(key); 880 } 881 882 return props.getProperty(key, def); 883 } 884 885 /** 886 * Sets the system property indicated by the specified key. 887 * 888 * First, if a security manager exists, its 889 * {@code SecurityManager.checkPermission} method 890 * is called with a {@code PropertyPermission(key, "write")} 891 * permission. This may result in a SecurityException being thrown. 892 * If no exception is thrown, the specified property is set to the given 893 * value. 894 * 895 * @apiNote 896 * <strong>Changing a standard system property may have unpredictable results 897 * unless otherwise specified</strong>. 898 * See {@linkplain #getProperties getProperties} for details. 899 * 900 * @param key the name of the system property. 901 * @param value the value of the system property. 902 * @return the previous value of the system property, 903 * or {@code null} if it did not have one. 904 * 905 * @throws SecurityException if a security manager exists and its 906 * {@code checkPermission} method doesn't allow 907 * setting of the specified property. 908 * @throws NullPointerException if {@code key} or 909 * {@code value} is {@code null}. 910 * @throws IllegalArgumentException if {@code key} is empty. 911 * @see #getProperty 912 * @see java.lang.System#getProperty(java.lang.String) 913 * @see java.lang.System#getProperty(java.lang.String, java.lang.String) 914 * @see java.util.PropertyPermission 915 * @see SecurityManager#checkPermission 916 * @since 1.2 917 */ 918 public static String setProperty(String key, String value) { 919 checkKey(key); 920 SecurityManager sm = getSecurityManager(); 921 if (sm != null) { 922 sm.checkPermission(new PropertyPermission(key, 923 SecurityConstants.PROPERTY_WRITE_ACTION)); 924 } 925 926 return (String) props.setProperty(key, value); 927 } 928 929 /** 930 * Removes the system property indicated by the specified key. 931 * 932 * First, if a security manager exists, its 933 * {@code SecurityManager.checkPermission} method 934 * is called with a {@code PropertyPermission(key, "write")} 935 * permission. This may result in a SecurityException being thrown. 936 * If no exception is thrown, the specified property is removed. 937 * 938 * @apiNote 939 * <strong>Changing a standard system property may have unpredictable results 940 * unless otherwise specified</strong>. 941 * See {@linkplain #getProperties getProperties} method for details. 942 * 943 * @param key the name of the system property to be removed. 944 * @return the previous string value of the system property, 945 * or {@code null} if there was no property with that key. 946 * 947 * @throws SecurityException if a security manager exists and its 948 * {@code checkPropertyAccess} method doesn't allow 949 * access to the specified system property. 950 * @throws NullPointerException if {@code key} is {@code null}. 951 * @throws IllegalArgumentException if {@code key} is empty. 952 * @see #getProperty 953 * @see #setProperty 954 * @see java.util.Properties 955 * @see java.lang.SecurityException 956 * @see java.lang.SecurityManager#checkPropertiesAccess() 957 * @since 1.5 958 */ 959 public static String clearProperty(String key) { 960 checkKey(key); 961 SecurityManager sm = getSecurityManager(); 962 if (sm != null) { 963 sm.checkPermission(new PropertyPermission(key, "write")); 964 } 965 966 return (String) props.remove(key); 967 } 968 969 private static void checkKey(String key) { 970 if (key == null) { 971 throw new NullPointerException("key can't be null"); 972 } 973 if (key.equals("")) { 974 throw new IllegalArgumentException("key can't be empty"); 975 } 976 } 977 978 /** 979 * Gets the value of the specified environment variable. An 980 * environment variable is a system-dependent external named 981 * value. 982 * 983 * <p>If a security manager exists, its 984 * {@link SecurityManager#checkPermission checkPermission} 985 * method is called with a 986 * {@code {@link RuntimePermission}("getenv."+name)} 987 * permission. This may result in a {@link SecurityException} 988 * being thrown. If no exception is thrown the value of the 989 * variable {@code name} is returned. 990 * 991 * <p><a id="EnvironmentVSSystemProperties"><i>System 992 * properties</i> and <i>environment variables</i></a> are both 993 * conceptually mappings between names and values. Both 994 * mechanisms can be used to pass user-defined information to a 995 * Java process. Environment variables have a more global effect, 996 * because they are visible to all descendants of the process 997 * which defines them, not just the immediate Java subprocess. 998 * They can have subtly different semantics, such as case 999 * insensitivity, on different operating systems. For these 1000 * reasons, environment variables are more likely to have 1001 * unintended side effects. It is best to use system properties 1002 * where possible. Environment variables should be used when a 1003 * global effect is desired, or when an external system interface 1004 * requires an environment variable (such as {@code PATH}). 1005 * 1006 * <p>On UNIX systems the alphabetic case of {@code name} is 1007 * typically significant, while on Microsoft Windows systems it is 1008 * typically not. For example, the expression 1009 * {@code System.getenv("FOO").equals(System.getenv("foo"))} 1010 * is likely to be true on Microsoft Windows. 1011 * 1012 * @param name the name of the environment variable 1013 * @return the string value of the variable, or {@code null} 1014 * if the variable is not defined in the system environment 1015 * @throws NullPointerException if {@code name} is {@code null} 1016 * @throws SecurityException 1017 * if a security manager exists and its 1018 * {@link SecurityManager#checkPermission checkPermission} 1019 * method doesn't allow access to the environment variable 1020 * {@code name} 1021 * @see #getenv() 1022 * @see ProcessBuilder#environment() 1023 */ 1024 public static String getenv(String name) { 1025 SecurityManager sm = getSecurityManager(); 1026 if (sm != null) { 1027 sm.checkPermission(new RuntimePermission("getenv."+name)); 1028 } 1029 1030 return ProcessEnvironment.getenv(name); 1031 } 1032 1033 1034 /** 1035 * Returns an unmodifiable string map view of the current system environment. 1036 * The environment is a system-dependent mapping from names to 1037 * values which is passed from parent to child processes. 1038 * 1039 * <p>If the system does not support environment variables, an 1040 * empty map is returned. 1041 * 1042 * <p>The returned map will never contain null keys or values. 1043 * Attempting to query the presence of a null key or value will 1044 * throw a {@link NullPointerException}. Attempting to query 1045 * the presence of a key or value which is not of type 1046 * {@link String} will throw a {@link ClassCastException}. 1047 * 1048 * <p>The returned map and its collection views may not obey the 1049 * general contract of the {@link Object#equals} and 1050 * {@link Object#hashCode} methods. 1051 * 1052 * <p>The returned map is typically case-sensitive on all platforms. 1053 * 1054 * <p>If a security manager exists, its 1055 * {@link SecurityManager#checkPermission checkPermission} 1056 * method is called with a 1057 * {@code {@link RuntimePermission}("getenv.*")} permission. 1058 * This may result in a {@link SecurityException} being thrown. 1059 * 1060 * <p>When passing information to a Java subprocess, 1061 * <a href=#EnvironmentVSSystemProperties>system properties</a> 1062 * are generally preferred over environment variables. 1063 * 1064 * @return the environment as a map of variable names to values 1065 * @throws SecurityException 1066 * if a security manager exists and its 1067 * {@link SecurityManager#checkPermission checkPermission} 1068 * method doesn't allow access to the process environment 1069 * @see #getenv(String) 1070 * @see ProcessBuilder#environment() 1071 * @since 1.5 1072 */ 1073 public static java.util.Map<String,String> getenv() { 1074 SecurityManager sm = getSecurityManager(); 1075 if (sm != null) { 1076 sm.checkPermission(new RuntimePermission("getenv.*")); 1077 } 1078 1079 return ProcessEnvironment.getenv(); 1080 } 1081 1082 /** 1083 * {@code System.Logger} instances log messages that will be 1084 * routed to the underlying logging framework the {@link System.LoggerFinder 1085 * LoggerFinder} uses. 1086 * 1087 * {@code System.Logger} instances are typically obtained from 1088 * the {@link java.lang.System System} class, by calling 1089 * {@link java.lang.System#getLogger(java.lang.String) System.getLogger(loggerName)} 1090 * or {@link java.lang.System#getLogger(java.lang.String, java.util.ResourceBundle) 1091 * System.getLogger(loggerName, bundle)}. 1092 * 1093 * @see java.lang.System#getLogger(java.lang.String) 1094 * @see java.lang.System#getLogger(java.lang.String, java.util.ResourceBundle) 1095 * @see java.lang.System.LoggerFinder 1096 * 1097 * @since 9 1098 */ 1099 public interface Logger { 1100 1101 /** 1102 * System {@linkplain Logger loggers} levels. 1103 * 1104 * A level has a {@linkplain #getName() name} and {@linkplain 1105 * #getSeverity() severity}. 1106 * Level values are {@link #ALL}, {@link #TRACE}, {@link #DEBUG}, 1107 * {@link #INFO}, {@link #WARNING}, {@link #ERROR}, {@link #OFF}, 1108 * by order of increasing severity. 1109 * <br> 1110 * {@link #ALL} and {@link #OFF} 1111 * are simple markers with severities mapped respectively to 1112 * {@link java.lang.Integer#MIN_VALUE Integer.MIN_VALUE} and 1113 * {@link java.lang.Integer#MAX_VALUE Integer.MAX_VALUE}. 1114 * <p> 1115 * <b>Severity values and Mapping to {@code java.util.logging.Level}.</b> 1116 * <p> 1117 * {@linkplain System.Logger.Level System logger levels} are mapped to 1118 * {@linkplain java.util.logging.Level java.util.logging levels} 1119 * of corresponding severity. 1120 * <br>The mapping is as follows: 1121 * <br><br> 1122 * <table class="striped"> 1123 * <caption>System.Logger Severity Level Mapping</caption> 1124 * <thead> 1125 * <tr><th scope="col">System.Logger Levels</th> 1126 * <th scope="col">java.util.logging Levels</th> 1127 * </thead> 1128 * <tbody> 1129 * <tr><th scope="row">{@link Logger.Level#ALL ALL}</th> 1130 * <td>{@link java.util.logging.Level#ALL ALL}</td> 1131 * <tr><th scope="row">{@link Logger.Level#TRACE TRACE}</th> 1132 * <td>{@link java.util.logging.Level#FINER FINER}</td> 1133 * <tr><th scope="row">{@link Logger.Level#DEBUG DEBUG}</th> 1134 * <td>{@link java.util.logging.Level#FINE FINE}</td> 1135 * <tr><th scope="row">{@link Logger.Level#INFO INFO}</th> 1136 * <td>{@link java.util.logging.Level#INFO INFO}</td> 1137 * <tr><th scope="row">{@link Logger.Level#WARNING WARNING}</th> 1138 * <td>{@link java.util.logging.Level#WARNING WARNING}</td> 1139 * <tr><th scope="row">{@link Logger.Level#ERROR ERROR}</th> 1140 * <td>{@link java.util.logging.Level#SEVERE SEVERE}</td> 1141 * <tr><th scope="row">{@link Logger.Level#OFF OFF}</th> 1142 * <td>{@link java.util.logging.Level#OFF OFF}</td> 1143 * </tbody> 1144 * </table> 1145 * 1146 * @since 9 1147 * 1148 * @see java.lang.System.LoggerFinder 1149 * @see java.lang.System.Logger 1150 */ 1151 public enum Level { 1152 1153 // for convenience, we're reusing java.util.logging.Level int values 1154 // the mapping logic in sun.util.logging.PlatformLogger depends 1155 // on this. 1156 /** 1157 * A marker to indicate that all levels are enabled. 1158 * This level {@linkplain #getSeverity() severity} is 1159 * {@link Integer#MIN_VALUE}. 1160 */ 1161 ALL(Integer.MIN_VALUE), // typically mapped to/from j.u.l.Level.ALL 1162 /** 1163 * {@code TRACE} level: usually used to log diagnostic information. 1164 * This level {@linkplain #getSeverity() severity} is 1165 * {@code 400}. 1166 */ 1167 TRACE(400), // typically mapped to/from j.u.l.Level.FINER 1168 /** 1169 * {@code DEBUG} level: usually used to log debug information traces. 1170 * This level {@linkplain #getSeverity() severity} is 1171 * {@code 500}. 1172 */ 1173 DEBUG(500), // typically mapped to/from j.u.l.Level.FINEST/FINE/CONFIG 1174 /** 1175 * {@code INFO} level: usually used to log information messages. 1176 * This level {@linkplain #getSeverity() severity} is 1177 * {@code 800}. 1178 */ 1179 INFO(800), // typically mapped to/from j.u.l.Level.INFO 1180 /** 1181 * {@code WARNING} level: usually used to log warning messages. 1182 * This level {@linkplain #getSeverity() severity} is 1183 * {@code 900}. 1184 */ 1185 WARNING(900), // typically mapped to/from j.u.l.Level.WARNING 1186 /** 1187 * {@code ERROR} level: usually used to log error messages. 1188 * This level {@linkplain #getSeverity() severity} is 1189 * {@code 1000}. 1190 */ 1191 ERROR(1000), // typically mapped to/from j.u.l.Level.SEVERE 1192 /** 1193 * A marker to indicate that all levels are disabled. 1194 * This level {@linkplain #getSeverity() severity} is 1195 * {@link Integer#MAX_VALUE}. 1196 */ 1197 OFF(Integer.MAX_VALUE); // typically mapped to/from j.u.l.Level.OFF 1198 1199 private final int severity; 1200 1201 private Level(int severity) { 1202 this.severity = severity; 1203 } 1204 1205 /** 1206 * Returns the name of this level. 1207 * @return this level {@linkplain #name()}. 1208 */ 1209 public final String getName() { 1210 return name(); 1211 } 1212 1213 /** 1214 * Returns the severity of this level. 1215 * A higher severity means a more severe condition. 1216 * @return this level severity. 1217 */ 1218 public final int getSeverity() { 1219 return severity; 1220 } 1221 } 1222 1223 /** 1224 * Returns the name of this logger. 1225 * 1226 * @return the logger name. 1227 */ 1228 public String getName(); 1229 1230 /** 1231 * Checks if a message of the given level would be logged by 1232 * this logger. 1233 * 1234 * @param level the log message level. 1235 * @return {@code true} if the given log message level is currently 1236 * being logged. 1237 * 1238 * @throws NullPointerException if {@code level} is {@code null}. 1239 */ 1240 public boolean isLoggable(Level level); 1241 1242 /** 1243 * Logs a message. 1244 * 1245 * @implSpec The default implementation for this method calls 1246 * {@code this.log(level, (ResourceBundle)null, msg, (Object[])null);} 1247 * 1248 * @param level the log message level. 1249 * @param msg the string message (or a key in the message catalog, if 1250 * this logger is a {@link 1251 * LoggerFinder#getLocalizedLogger(java.lang.String, 1252 * java.util.ResourceBundle, java.lang.Module) localized logger}); 1253 * can be {@code null}. 1254 * 1255 * @throws NullPointerException if {@code level} is {@code null}. 1256 */ 1257 public default void log(Level level, String msg) { 1258 log(level, (ResourceBundle) null, msg, (Object[]) null); 1259 } 1260 1261 /** 1262 * Logs a lazily supplied message. 1263 * 1264 * If the logger is currently enabled for the given log message level 1265 * then a message is logged that is the result produced by the 1266 * given supplier function. Otherwise, the supplier is not operated on. 1267 * 1268 * @implSpec When logging is enabled for the given level, the default 1269 * implementation for this method calls 1270 * {@code this.log(level, (ResourceBundle)null, msgSupplier.get(), (Object[])null);} 1271 * 1272 * @param level the log message level. 1273 * @param msgSupplier a supplier function that produces a message. 1274 * 1275 * @throws NullPointerException if {@code level} is {@code null}, 1276 * or {@code msgSupplier} is {@code null}. 1277 */ 1278 public default void log(Level level, Supplier<String> msgSupplier) { 1279 Objects.requireNonNull(msgSupplier); 1280 if (isLoggable(Objects.requireNonNull(level))) { 1281 log(level, (ResourceBundle) null, msgSupplier.get(), (Object[]) null); 1282 } 1283 } 1284 1285 /** 1286 * Logs a message produced from the given object. 1287 * 1288 * If the logger is currently enabled for the given log message level then 1289 * a message is logged that, by default, is the result produced from 1290 * calling toString on the given object. 1291 * Otherwise, the object is not operated on. 1292 * 1293 * @implSpec When logging is enabled for the given level, the default 1294 * implementation for this method calls 1295 * {@code this.log(level, (ResourceBundle)null, obj.toString(), (Object[])null);} 1296 * 1297 * @param level the log message level. 1298 * @param obj the object to log. 1299 * 1300 * @throws NullPointerException if {@code level} is {@code null}, or 1301 * {@code obj} is {@code null}. 1302 */ 1303 public default void log(Level level, Object obj) { 1304 Objects.requireNonNull(obj); 1305 if (isLoggable(Objects.requireNonNull(level))) { 1306 this.log(level, (ResourceBundle) null, obj.toString(), (Object[]) null); 1307 } 1308 } 1309 1310 /** 1311 * Logs a message associated with a given throwable. 1312 * 1313 * @implSpec The default implementation for this method calls 1314 * {@code this.log(level, (ResourceBundle)null, msg, thrown);} 1315 * 1316 * @param level the log message level. 1317 * @param msg the string message (or a key in the message catalog, if 1318 * this logger is a {@link 1319 * LoggerFinder#getLocalizedLogger(java.lang.String, 1320 * java.util.ResourceBundle, java.lang.Module) localized logger}); 1321 * can be {@code null}. 1322 * @param thrown a {@code Throwable} associated with the log message; 1323 * can be {@code null}. 1324 * 1325 * @throws NullPointerException if {@code level} is {@code null}. 1326 */ 1327 public default void log(Level level, String msg, Throwable thrown) { 1328 this.log(level, null, msg, thrown); 1329 } 1330 1331 /** 1332 * Logs a lazily supplied message associated with a given throwable. 1333 * 1334 * If the logger is currently enabled for the given log message level 1335 * then a message is logged that is the result produced by the 1336 * given supplier function. Otherwise, the supplier is not operated on. 1337 * 1338 * @implSpec When logging is enabled for the given level, the default 1339 * implementation for this method calls 1340 * {@code this.log(level, (ResourceBundle)null, msgSupplier.get(), thrown);} 1341 * 1342 * @param level one of the log message level identifiers. 1343 * @param msgSupplier a supplier function that produces a message. 1344 * @param thrown a {@code Throwable} associated with log message; 1345 * can be {@code null}. 1346 * 1347 * @throws NullPointerException if {@code level} is {@code null}, or 1348 * {@code msgSupplier} is {@code null}. 1349 */ 1350 public default void log(Level level, Supplier<String> msgSupplier, 1351 Throwable thrown) { 1352 Objects.requireNonNull(msgSupplier); 1353 if (isLoggable(Objects.requireNonNull(level))) { 1354 this.log(level, null, msgSupplier.get(), thrown); 1355 } 1356 } 1357 1358 /** 1359 * Logs a message with an optional list of parameters. 1360 * 1361 * @implSpec The default implementation for this method calls 1362 * {@code this.log(level, (ResourceBundle)null, format, params);} 1363 * 1364 * @param level one of the log message level identifiers. 1365 * @param format the string message format in {@link 1366 * java.text.MessageFormat} format, (or a key in the message 1367 * catalog, if this logger is a {@link 1368 * LoggerFinder#getLocalizedLogger(java.lang.String, 1369 * java.util.ResourceBundle, java.lang.Module) localized logger}); 1370 * can be {@code null}. 1371 * @param params an optional list of parameters to the message (may be 1372 * none). 1373 * 1374 * @throws NullPointerException if {@code level} is {@code null}. 1375 */ 1376 public default void log(Level level, String format, Object... params) { 1377 this.log(level, null, format, params); 1378 } 1379 1380 /** 1381 * Logs a localized message associated with a given throwable. 1382 * 1383 * If the given resource bundle is non-{@code null}, the {@code msg} 1384 * string is localized using the given resource bundle. 1385 * Otherwise the {@code msg} string is not localized. 1386 * 1387 * @param level the log message level. 1388 * @param bundle a resource bundle to localize {@code msg}; can be 1389 * {@code null}. 1390 * @param msg the string message (or a key in the message catalog, 1391 * if {@code bundle} is not {@code null}); can be {@code null}. 1392 * @param thrown a {@code Throwable} associated with the log message; 1393 * can be {@code null}. 1394 * 1395 * @throws NullPointerException if {@code level} is {@code null}. 1396 */ 1397 public void log(Level level, ResourceBundle bundle, String msg, 1398 Throwable thrown); 1399 1400 /** 1401 * Logs a message with resource bundle and an optional list of 1402 * parameters. 1403 * 1404 * If the given resource bundle is non-{@code null}, the {@code format} 1405 * string is localized using the given resource bundle. 1406 * Otherwise the {@code format} string is not localized. 1407 * 1408 * @param level the log message level. 1409 * @param bundle a resource bundle to localize {@code format}; can be 1410 * {@code null}. 1411 * @param format the string message format in {@link 1412 * java.text.MessageFormat} format, (or a key in the message 1413 * catalog if {@code bundle} is not {@code null}); can be {@code null}. 1414 * @param params an optional list of parameters to the message (may be 1415 * none). 1416 * 1417 * @throws NullPointerException if {@code level} is {@code null}. 1418 */ 1419 public void log(Level level, ResourceBundle bundle, String format, 1420 Object... params); 1421 } 1422 1423 /** 1424 * The {@code LoggerFinder} service is responsible for creating, managing, 1425 * and configuring loggers to the underlying framework it uses. 1426 * 1427 * A logger finder is a concrete implementation of this class that has a 1428 * zero-argument constructor and implements the abstract methods defined 1429 * by this class. 1430 * The loggers returned from a logger finder are capable of routing log 1431 * messages to the logging backend this provider supports. 1432 * A given invocation of the Java Runtime maintains a single 1433 * system-wide LoggerFinder instance that is loaded as follows: 1434 * <ul> 1435 * <li>First it finds any custom {@code LoggerFinder} provider 1436 * using the {@link java.util.ServiceLoader} facility with the 1437 * {@linkplain ClassLoader#getSystemClassLoader() system class 1438 * loader}.</li> 1439 * <li>If no {@code LoggerFinder} provider is found, the system default 1440 * {@code LoggerFinder} implementation will be used.</li> 1441 * </ul> 1442 * <p> 1443 * An application can replace the logging backend 1444 * <i>even when the java.logging module is present</i>, by simply providing 1445 * and declaring an implementation of the {@link LoggerFinder} service. 1446 * <p> 1447 * <b>Default Implementation</b> 1448 * <p> 1449 * The system default {@code LoggerFinder} implementation uses 1450 * {@code java.util.logging} as the backend framework when the 1451 * {@code java.logging} module is present. 1452 * It returns a {@linkplain System.Logger logger} instance 1453 * that will route log messages to a {@link java.util.logging.Logger 1454 * java.util.logging.Logger}. Otherwise, if {@code java.logging} is not 1455 * present, the default implementation will return a simple logger 1456 * instance that will route log messages of {@code INFO} level and above to 1457 * the console ({@code System.err}). 1458 * <p> 1459 * <b>Logging Configuration</b> 1460 * <p> 1461 * {@linkplain Logger Logger} instances obtained from the 1462 * {@code LoggerFinder} factory methods are not directly configurable by 1463 * the application. Configuration is the responsibility of the underlying 1464 * logging backend, and usually requires using APIs specific to that backend. 1465 * <p>For the default {@code LoggerFinder} implementation 1466 * using {@code java.util.logging} as its backend, refer to 1467 * {@link java.util.logging java.util.logging} for logging configuration. 1468 * For the default {@code LoggerFinder} implementation returning simple loggers 1469 * when the {@code java.logging} module is absent, the configuration 1470 * is implementation dependent. 1471 * <p> 1472 * Usually an application that uses a logging framework will log messages 1473 * through a logger facade defined (or supported) by that framework. 1474 * Applications that wish to use an external framework should log 1475 * through the facade associated with that framework. 1476 * <p> 1477 * A system class that needs to log messages will typically obtain 1478 * a {@link System.Logger} instance to route messages to the logging 1479 * framework selected by the application. 1480 * <p> 1481 * Libraries and classes that only need loggers to produce log messages 1482 * should not attempt to configure loggers by themselves, as that 1483 * would make them dependent from a specific implementation of the 1484 * {@code LoggerFinder} service. 1485 * <p> 1486 * In addition, when a security manager is present, loggers provided to 1487 * system classes should not be directly configurable through the logging 1488 * backend without requiring permissions. 1489 * <br> 1490 * It is the responsibility of the provider of 1491 * the concrete {@code LoggerFinder} implementation to ensure that 1492 * these loggers are not configured by untrusted code without proper 1493 * permission checks, as configuration performed on such loggers usually 1494 * affects all applications in the same Java Runtime. 1495 * <p> 1496 * <b>Message Levels and Mapping to backend levels</b> 1497 * <p> 1498 * A logger finder is responsible for mapping from a {@code 1499 * System.Logger.Level} to a level supported by the logging backend it uses. 1500 * <br>The default LoggerFinder using {@code java.util.logging} as the backend 1501 * maps {@code System.Logger} levels to 1502 * {@linkplain java.util.logging.Level java.util.logging} levels 1503 * of corresponding severity - as described in {@link Logger.Level 1504 * Logger.Level}. 1505 * 1506 * @see java.lang.System 1507 * @see java.lang.System.Logger 1508 * 1509 * @since 9 1510 */ 1511 public static abstract class LoggerFinder { 1512 /** 1513 * The {@code RuntimePermission("loggerFinder")} is 1514 * necessary to subclass and instantiate the {@code LoggerFinder} class, 1515 * as well as to obtain loggers from an instance of that class. 1516 */ 1517 static final RuntimePermission LOGGERFINDER_PERMISSION = 1518 new RuntimePermission("loggerFinder"); 1519 1520 /** 1521 * Creates a new instance of {@code LoggerFinder}. 1522 * 1523 * @implNote It is recommended that a {@code LoggerFinder} service 1524 * implementation does not perform any heavy initialization in its 1525 * constructor, in order to avoid possible risks of deadlock or class 1526 * loading cycles during the instantiation of the service provider. 1527 * 1528 * @throws SecurityException if a security manager is present and its 1529 * {@code checkPermission} method doesn't allow the 1530 * {@code RuntimePermission("loggerFinder")}. 1531 */ 1532 protected LoggerFinder() { 1533 this(checkPermission()); 1534 } 1535 1536 private LoggerFinder(Void unused) { 1537 // nothing to do. 1538 } 1539 1540 private static Void checkPermission() { 1541 final SecurityManager sm = System.getSecurityManager(); 1542 if (sm != null) { 1543 sm.checkPermission(LOGGERFINDER_PERMISSION); 1544 } 1545 return null; 1546 } 1547 1548 /** 1549 * Returns an instance of {@link Logger Logger} 1550 * for the given {@code module}. 1551 * 1552 * @param name the name of the logger. 1553 * @param module the module for which the logger is being requested. 1554 * 1555 * @return a {@link Logger logger} suitable for use within the given 1556 * module. 1557 * @throws NullPointerException if {@code name} is {@code null} or 1558 * {@code module} is {@code null}. 1559 * @throws SecurityException if a security manager is present and its 1560 * {@code checkPermission} method doesn't allow the 1561 * {@code RuntimePermission("loggerFinder")}. 1562 */ 1563 public abstract Logger getLogger(String name, Module module); 1564 1565 /** 1566 * Returns a localizable instance of {@link Logger Logger} 1567 * for the given {@code module}. 1568 * The returned logger will use the provided resource bundle for 1569 * message localization. 1570 * 1571 * @implSpec By default, this method calls {@link 1572 * #getLogger(java.lang.String, java.lang.Module) 1573 * this.getLogger(name, module)} to obtain a logger, then wraps that 1574 * logger in a {@link Logger} instance where all methods that do not 1575 * take a {@link ResourceBundle} as parameter are redirected to one 1576 * which does - passing the given {@code bundle} for 1577 * localization. So for instance, a call to {@link 1578 * Logger#log(Logger.Level, String) Logger.log(Level.INFO, msg)} 1579 * will end up as a call to {@link 1580 * Logger#log(Logger.Level, ResourceBundle, String, Object...) 1581 * Logger.log(Level.INFO, bundle, msg, (Object[])null)} on the wrapped 1582 * logger instance. 1583 * Note however that by default, string messages returned by {@link 1584 * java.util.function.Supplier Supplier<String>} will not be 1585 * localized, as it is assumed that such strings are messages which are 1586 * already constructed, rather than keys in a resource bundle. 1587 * <p> 1588 * An implementation of {@code LoggerFinder} may override this method, 1589 * for example, when the underlying logging backend provides its own 1590 * mechanism for localizing log messages, then such a 1591 * {@code LoggerFinder} would be free to return a logger 1592 * that makes direct use of the mechanism provided by the backend. 1593 * 1594 * @param name the name of the logger. 1595 * @param bundle a resource bundle; can be {@code null}. 1596 * @param module the module for which the logger is being requested. 1597 * @return an instance of {@link Logger Logger} which will use the 1598 * provided resource bundle for message localization. 1599 * 1600 * @throws NullPointerException if {@code name} is {@code null} or 1601 * {@code module} is {@code null}. 1602 * @throws SecurityException if a security manager is present and its 1603 * {@code checkPermission} method doesn't allow the 1604 * {@code RuntimePermission("loggerFinder")}. 1605 */ 1606 public Logger getLocalizedLogger(String name, ResourceBundle bundle, 1607 Module module) { 1608 return new LocalizedLoggerWrapper<>(getLogger(name, module), bundle); 1609 } 1610 1611 /** 1612 * Returns the {@code LoggerFinder} instance. There is one 1613 * single system-wide {@code LoggerFinder} instance in 1614 * the Java Runtime. See the class specification of how the 1615 * {@link LoggerFinder LoggerFinder} implementation is located and 1616 * loaded. 1617 1618 * @return the {@link LoggerFinder LoggerFinder} instance. 1619 * @throws SecurityException if a security manager is present and its 1620 * {@code checkPermission} method doesn't allow the 1621 * {@code RuntimePermission("loggerFinder")}. 1622 */ 1623 public static LoggerFinder getLoggerFinder() { 1624 final SecurityManager sm = System.getSecurityManager(); 1625 if (sm != null) { 1626 sm.checkPermission(LOGGERFINDER_PERMISSION); 1627 } 1628 return accessProvider(); 1629 } 1630 1631 1632 private static volatile LoggerFinder service; 1633 static LoggerFinder accessProvider() { 1634 // We do not need to synchronize: LoggerFinderLoader will 1635 // always return the same instance, so if we don't have it, 1636 // just fetch it again. 1637 if (service == null) { 1638 PrivilegedAction<LoggerFinder> pa = 1639 () -> LoggerFinderLoader.getLoggerFinder(); 1640 service = AccessController.doPrivileged(pa, null, 1641 LOGGERFINDER_PERMISSION); 1642 } 1643 return service; 1644 } 1645 1646 } 1647 1648 1649 /** 1650 * Returns an instance of {@link Logger Logger} for the caller's 1651 * use. 1652 * 1653 * @implSpec 1654 * Instances returned by this method route messages to loggers 1655 * obtained by calling {@link LoggerFinder#getLogger(java.lang.String, 1656 * java.lang.Module) LoggerFinder.getLogger(name, module)}, where 1657 * {@code module} is the caller's module. 1658 * In cases where {@code System.getLogger} is called from a context where 1659 * there is no caller frame on the stack (e.g when called directly 1660 * from a JNI attached thread), {@code IllegalCallerException} is thrown. 1661 * To obtain a logger in such a context, use an auxiliary class that will 1662 * implicitly be identified as the caller, or use the system {@link 1663 * LoggerFinder#getLoggerFinder() LoggerFinder} to obtain a logger instead. 1664 * Note that doing the latter may eagerly initialize the underlying 1665 * logging system. 1666 * 1667 * @apiNote 1668 * This method may defer calling the {@link 1669 * LoggerFinder#getLogger(java.lang.String, java.lang.Module) 1670 * LoggerFinder.getLogger} method to create an actual logger supplied by 1671 * the logging backend, for instance, to allow loggers to be obtained during 1672 * the system initialization time. 1673 * 1674 * @param name the name of the logger. 1675 * @return an instance of {@link Logger} that can be used by the calling 1676 * class. 1677 * @throws NullPointerException if {@code name} is {@code null}. 1678 * @throws IllegalCallerException if there is no Java caller frame on the 1679 * stack. 1680 * 1681 * @since 9 1682 */ 1683 @CallerSensitive 1684 public static Logger getLogger(String name) { 1685 Objects.requireNonNull(name); 1686 final Class<?> caller = Reflection.getCallerClass(); 1687 if (caller == null) { 1688 throw new IllegalCallerException("no caller frame"); 1689 } 1690 return LazyLoggers.getLogger(name, caller.getModule()); 1691 } 1692 1693 /** 1694 * Returns a localizable instance of {@link Logger 1695 * Logger} for the caller's use. 1696 * The returned logger will use the provided resource bundle for message 1697 * localization. 1698 * 1699 * @implSpec 1700 * The returned logger will perform message localization as specified 1701 * by {@link LoggerFinder#getLocalizedLogger(java.lang.String, 1702 * java.util.ResourceBundle, java.lang.Module) 1703 * LoggerFinder.getLocalizedLogger(name, bundle, module)}, where 1704 * {@code module} is the caller's module. 1705 * In cases where {@code System.getLogger} is called from a context where 1706 * there is no caller frame on the stack (e.g when called directly 1707 * from a JNI attached thread), {@code IllegalCallerException} is thrown. 1708 * To obtain a logger in such a context, use an auxiliary class that 1709 * will implicitly be identified as the caller, or use the system {@link 1710 * LoggerFinder#getLoggerFinder() LoggerFinder} to obtain a logger instead. 1711 * Note that doing the latter may eagerly initialize the underlying 1712 * logging system. 1713 * 1714 * @apiNote 1715 * This method is intended to be used after the system is fully initialized. 1716 * This method may trigger the immediate loading and initialization 1717 * of the {@link LoggerFinder} service, which may cause issues if the 1718 * Java Runtime is not ready to initialize the concrete service 1719 * implementation yet. 1720 * System classes which may be loaded early in the boot sequence and 1721 * need to log localized messages should create a logger using 1722 * {@link #getLogger(java.lang.String)} and then use the log methods that 1723 * take a resource bundle as parameter. 1724 * 1725 * @param name the name of the logger. 1726 * @param bundle a resource bundle. 1727 * @return an instance of {@link Logger} which will use the provided 1728 * resource bundle for message localization. 1729 * @throws NullPointerException if {@code name} is {@code null} or 1730 * {@code bundle} is {@code null}. 1731 * @throws IllegalCallerException if there is no Java caller frame on the 1732 * stack. 1733 * 1734 * @since 9 1735 */ 1736 @CallerSensitive 1737 public static Logger getLogger(String name, ResourceBundle bundle) { 1738 final ResourceBundle rb = Objects.requireNonNull(bundle); 1739 Objects.requireNonNull(name); 1740 final Class<?> caller = Reflection.getCallerClass(); 1741 if (caller == null) { 1742 throw new IllegalCallerException("no caller frame"); 1743 } 1744 final SecurityManager sm = System.getSecurityManager(); 1745 // We don't use LazyLoggers if a resource bundle is specified. 1746 // Bootstrap sensitive classes in the JDK do not use resource bundles 1747 // when logging. This could be revisited later, if it needs to. 1748 if (sm != null) { 1749 final PrivilegedAction<Logger> pa = 1750 () -> LoggerFinder.accessProvider() 1751 .getLocalizedLogger(name, rb, caller.getModule()); 1752 return AccessController.doPrivileged(pa, null, 1753 LoggerFinder.LOGGERFINDER_PERMISSION); 1754 } 1755 return LoggerFinder.accessProvider() 1756 .getLocalizedLogger(name, rb, caller.getModule()); 1757 } 1758 1759 /** 1760 * Terminates the currently running Java Virtual Machine. The 1761 * argument serves as a status code; by convention, a nonzero status 1762 * code indicates abnormal termination. 1763 * <p> 1764 * This method calls the {@code exit} method in class 1765 * {@code Runtime}. This method never returns normally. 1766 * <p> 1767 * The call {@code System.exit(n)} is effectively equivalent to 1768 * the call: 1769 * <blockquote><pre> 1770 * Runtime.getRuntime().exit(n) 1771 * </pre></blockquote> 1772 * 1773 * @param status exit status. 1774 * @throws SecurityException 1775 * if a security manager exists and its {@code checkExit} 1776 * method doesn't allow exit with the specified status. 1777 * @see java.lang.Runtime#exit(int) 1778 */ 1779 public static void exit(int status) { 1780 Runtime.getRuntime().exit(status); 1781 } 1782 1783 /** 1784 * Runs the garbage collector. 1785 * 1786 * Calling the {@code gc} method suggests that the Java Virtual 1787 * Machine expend effort toward recycling unused objects in order to 1788 * make the memory they currently occupy available for quick reuse. 1789 * When control returns from the method call, the Java Virtual 1790 * Machine has made a best effort to reclaim space from all discarded 1791 * objects. 1792 * <p> 1793 * The call {@code System.gc()} is effectively equivalent to the 1794 * call: 1795 * <blockquote><pre> 1796 * Runtime.getRuntime().gc() 1797 * </pre></blockquote> 1798 * 1799 * @see java.lang.Runtime#gc() 1800 */ 1801 public static void gc() { 1802 Runtime.getRuntime().gc(); 1803 } 1804 1805 /** 1806 * Runs the finalization methods of any objects pending finalization. 1807 * 1808 * Calling this method suggests that the Java Virtual Machine expend 1809 * effort toward running the {@code finalize} methods of objects 1810 * that have been found to be discarded but whose {@code finalize} 1811 * methods have not yet been run. When control returns from the 1812 * method call, the Java Virtual Machine has made a best effort to 1813 * complete all outstanding finalizations. 1814 * <p> 1815 * The call {@code System.runFinalization()} is effectively 1816 * equivalent to the call: 1817 * <blockquote><pre> 1818 * Runtime.getRuntime().runFinalization() 1819 * </pre></blockquote> 1820 * 1821 * @see java.lang.Runtime#runFinalization() 1822 */ 1823 public static void runFinalization() { 1824 Runtime.getRuntime().runFinalization(); 1825 } 1826 1827 /** 1828 * Loads the native library specified by the filename argument. The filename 1829 * argument must be an absolute path name. 1830 * 1831 * If the filename argument, when stripped of any platform-specific library 1832 * prefix, path, and file extension, indicates a library whose name is, 1833 * for example, L, and a native library called L is statically linked 1834 * with the VM, then the JNI_OnLoad_L function exported by the library 1835 * is invoked rather than attempting to load a dynamic library. 1836 * A filename matching the argument does not have to exist in the 1837 * file system. 1838 * See the <a href="{@docRoot}/../specs/jni/index.html"> JNI Specification</a> 1839 * for more details. 1840 * 1841 * Otherwise, the filename argument is mapped to a native library image in 1842 * an implementation-dependent manner. 1843 * 1844 * <p> 1845 * The call {@code System.load(name)} is effectively equivalent 1846 * to the call: 1847 * <blockquote><pre> 1848 * Runtime.getRuntime().load(name) 1849 * </pre></blockquote> 1850 * 1851 * @param filename the file to load. 1852 * @throws SecurityException if a security manager exists and its 1853 * {@code checkLink} method doesn't allow 1854 * loading of the specified dynamic library 1855 * @throws UnsatisfiedLinkError if either the filename is not an 1856 * absolute path name, the native library is not statically 1857 * linked with the VM, or the library cannot be mapped to 1858 * a native library image by the host system. 1859 * @throws NullPointerException if {@code filename} is {@code null} 1860 * @see java.lang.Runtime#load(java.lang.String) 1861 * @see java.lang.SecurityManager#checkLink(java.lang.String) 1862 */ 1863 @CallerSensitive 1864 public static void load(String filename) { 1865 Runtime.getRuntime().load0(Reflection.getCallerClass(), filename); 1866 } 1867 1868 /** 1869 * Loads the native library specified by the {@code libname} 1870 * argument. The {@code libname} argument must not contain any platform 1871 * specific prefix, file extension or path. If a native library 1872 * called {@code libname} is statically linked with the VM, then the 1873 * JNI_OnLoad_{@code libname} function exported by the library is invoked. 1874 * See the <a href="{@docRoot}/../specs/jni/index.html"> JNI Specification</a> 1875 * for more details. 1876 * 1877 * Otherwise, the libname argument is loaded from a system library 1878 * location and mapped to a native library image in an implementation- 1879 * dependent manner. 1880 * <p> 1881 * The call {@code System.loadLibrary(name)} is effectively 1882 * equivalent to the call 1883 * <blockquote><pre> 1884 * Runtime.getRuntime().loadLibrary(name) 1885 * </pre></blockquote> 1886 * 1887 * @param libname the name of the library. 1888 * @throws SecurityException if a security manager exists and its 1889 * {@code checkLink} method doesn't allow 1890 * loading of the specified dynamic library 1891 * @throws UnsatisfiedLinkError if either the libname argument 1892 * contains a file path, the native library is not statically 1893 * linked with the VM, or the library cannot be mapped to a 1894 * native library image by the host system. 1895 * @throws NullPointerException if {@code libname} is {@code null} 1896 * @see java.lang.Runtime#loadLibrary(java.lang.String) 1897 * @see java.lang.SecurityManager#checkLink(java.lang.String) 1898 */ 1899 @CallerSensitive 1900 public static void loadLibrary(String libname) { 1901 Runtime.getRuntime().loadLibrary0(Reflection.getCallerClass(), libname); 1902 } 1903 1904 /** 1905 * Maps a library name into a platform-specific string representing 1906 * a native library. 1907 * 1908 * @param libname the name of the library. 1909 * @return a platform-dependent native library name. 1910 * @throws NullPointerException if {@code libname} is {@code null} 1911 * @see java.lang.System#loadLibrary(java.lang.String) 1912 * @see java.lang.ClassLoader#findLibrary(java.lang.String) 1913 * @since 1.2 1914 */ 1915 public static native String mapLibraryName(String libname); 1916 1917 /** 1918 * Create PrintStream for stdout/err based on encoding. 1919 */ 1920 private static PrintStream newPrintStream(FileOutputStream fos, String enc) { 1921 if (enc != null) { 1922 try { 1923 return new PrintStream(new BufferedOutputStream(fos, 128), true, enc); 1924 } catch (UnsupportedEncodingException uee) {} 1925 } 1926 return new PrintStream(new BufferedOutputStream(fos, 128), true); 1927 } 1928 1929 /** 1930 * Logs an exception/error at initialization time to stdout or stderr. 1931 * 1932 * @param printToStderr to print to stderr rather than stdout 1933 * @param printStackTrace to print the stack trace 1934 * @param msg the message to print before the exception, can be {@code null} 1935 * @param e the exception or error 1936 */ 1937 private static void logInitException(boolean printToStderr, 1938 boolean printStackTrace, 1939 String msg, 1940 Throwable e) { 1941 if (VM.initLevel() < 1) { 1942 throw new InternalError("system classes not initialized"); 1943 } 1944 PrintStream log = (printToStderr) ? err : out; 1945 if (msg != null) { 1946 log.println(msg); 1947 } 1948 if (printStackTrace) { 1949 e.printStackTrace(log); 1950 } else { 1951 log.println(e); 1952 for (Throwable suppressed : e.getSuppressed()) { 1953 log.println("Suppressed: " + suppressed); 1954 } 1955 Throwable cause = e.getCause(); 1956 if (cause != null) { 1957 log.println("Caused by: " + cause); 1958 } 1959 } 1960 } 1961 1962 /** 1963 * Initialize the system class. Called after thread initialization. 1964 */ 1965 private static void initPhase1() { 1966 1967 // VM might invoke JNU_NewStringPlatform() to set those encoding 1968 // sensitive properties (user.home, user.name, boot.class.path, etc.) 1969 // during "props" initialization, in which it may need access, via 1970 // System.getProperty(), to the related system encoding property that 1971 // have been initialized (put into "props") at early stage of the 1972 // initialization. So make sure the "props" is available at the 1973 // very beginning of the initialization and all system properties to 1974 // be put into it directly. 1975 props = new Properties(84); 1976 initProperties(props); // initialized by the VM 1977 VersionProps.init(props); 1978 1979 // There are certain system configurations that may be controlled by 1980 // VM options such as the maximum amount of direct memory and 1981 // Integer cache size used to support the object identity semantics 1982 // of autoboxing. Typically, the library will obtain these values 1983 // from the properties set by the VM. If the properties are for 1984 // internal implementation use only, these properties should be 1985 // removed from the system properties. 1986 // 1987 // See java.lang.Integer.IntegerCache and the 1988 // VM.saveAndRemoveProperties method for example. 1989 // 1990 // Save a private copy of the system properties object that 1991 // can only be accessed by the internal implementation. Remove 1992 // certain system properties that are not intended for public access. 1993 VM.saveAndRemoveProperties(props); 1994 1995 lineSeparator = props.getProperty("line.separator"); 1996 StaticProperty.javaHome(); // Load StaticProperty to cache the property values 1997 1998 FileInputStream fdIn = new FileInputStream(FileDescriptor.in); 1999 FileOutputStream fdOut = new FileOutputStream(FileDescriptor.out); 2000 FileOutputStream fdErr = new FileOutputStream(FileDescriptor.err); 2001 setIn0(new BufferedInputStream(fdIn)); 2002 setOut0(newPrintStream(fdOut, props.getProperty("sun.stdout.encoding"))); 2003 setErr0(newPrintStream(fdErr, props.getProperty("sun.stderr.encoding"))); 2004 2005 // Setup Java signal handlers for HUP, TERM, and INT (where available). 2006 Terminator.setup(); 2007 2008 // Initialize any miscellaneous operating system settings that need to be 2009 // set for the class libraries. Currently this is no-op everywhere except 2010 // for Windows where the process-wide error mode is set before the java.io 2011 // classes are used. 2012 VM.initializeOSEnvironment(); 2013 2014 // The main thread is not added to its thread group in the same 2015 // way as other threads; we must do it ourselves here. 2016 Thread current = Thread.currentThread(); 2017 current.getThreadGroup().add(current); 2018 2019 // register shared secrets 2020 setJavaLangAccess(); 2021 2022 // Subsystems that are invoked during initialization can invoke 2023 // VM.isBooted() in order to avoid doing things that should 2024 // wait until the VM is fully initialized. The initialization level 2025 // is incremented from 0 to 1 here to indicate the first phase of 2026 // initialization has completed. 2027 // IMPORTANT: Ensure that this remains the last initialization action! 2028 VM.initLevel(1); 2029 } 2030 2031 // @see #initPhase2() 2032 static ModuleLayer bootLayer; 2033 2034 /* 2035 * Invoked by VM. Phase 2 module system initialization. 2036 * Only classes in java.base can be loaded in this phase. 2037 * 2038 * @param printToStderr print exceptions to stderr rather than stdout 2039 * @param printStackTrace print stack trace when exception occurs 2040 * 2041 * @return JNI_OK for success, JNI_ERR for failure 2042 */ 2043 private static int initPhase2(boolean printToStderr, boolean printStackTrace) { 2044 try { 2045 bootLayer = ModuleBootstrap.boot(); 2046 } catch (Exception | Error e) { 2047 logInitException(printToStderr, printStackTrace, 2048 "Error occurred during initialization of boot layer", e); 2049 return -1; // JNI_ERR 2050 } 2051 2052 // module system initialized 2053 VM.initLevel(2); 2054 2055 return 0; // JNI_OK 2056 } 2057 2058 /* 2059 * Invoked by VM. Phase 3 is the final system initialization: 2060 * 1. set security manager 2061 * 2. set system class loader 2062 * 3. set TCCL 2063 * 2064 * This method must be called after the module system initialization. 2065 * The security manager and system class loader may be a custom class from 2066 * the application classpath or modulepath. 2067 */ 2068 private static void initPhase3() { 2069 String smProp = System.getProperty("java.security.manager"); 2070 if (smProp != null) { 2071 switch (smProp) { 2072 case "disallow": 2073 allowSecurityManager = NEVER; 2074 break; 2075 case "allow": 2076 allowSecurityManager = MAYBE; 2077 break; 2078 case "": 2079 case "default": 2080 setSecurityManager(new SecurityManager()); 2081 allowSecurityManager = MAYBE; 2082 break; 2083 default: 2084 try { 2085 ClassLoader cl = ClassLoader.getBuiltinAppClassLoader(); 2086 Class<?> c = Class.forName(smProp, false, cl); 2087 Constructor<?> ctor = c.getConstructor(); 2088 // Must be a public subclass of SecurityManager with 2089 // a public no-arg constructor 2090 if (!SecurityManager.class.isAssignableFrom(c) || 2091 !Modifier.isPublic(c.getModifiers()) || 2092 !Modifier.isPublic(ctor.getModifiers())) { 2093 throw new Error("Could not create SecurityManager: " 2094 + ctor.toString()); 2095 } 2096 // custom security manager may be in non-exported package 2097 ctor.setAccessible(true); 2098 SecurityManager sm = (SecurityManager) ctor.newInstance(); 2099 setSecurityManager(sm); 2100 } catch (Exception e) { 2101 throw new InternalError("Could not create SecurityManager", e); 2102 } 2103 allowSecurityManager = MAYBE; 2104 } 2105 } else { 2106 allowSecurityManager = MAYBE; 2107 } 2108 2109 // initializing the system class loader 2110 VM.initLevel(3); 2111 2112 // system class loader initialized 2113 ClassLoader scl = ClassLoader.initSystemClassLoader(); 2114 2115 // set TCCL 2116 Thread.currentThread().setContextClassLoader(scl); 2117 2118 // system is fully initialized 2119 VM.initLevel(4); 2120 } 2121 2122 private static void setJavaLangAccess() { 2123 // Allow privileged classes outside of java.lang 2124 SharedSecrets.setJavaLangAccess(new JavaLangAccess() { 2125 public List<Method> getDeclaredPublicMethods(Class<?> klass, String name, Class<?>... parameterTypes) { 2126 return klass.getDeclaredPublicMethods(name, parameterTypes); 2127 } 2128 public jdk.internal.reflect.ConstantPool getConstantPool(Class<?> klass) { 2129 return klass.getConstantPool(); 2130 } 2131 public boolean casAnnotationType(Class<?> klass, AnnotationType oldType, AnnotationType newType) { 2132 return klass.casAnnotationType(oldType, newType); 2133 } 2134 public AnnotationType getAnnotationType(Class<?> klass) { 2135 return klass.getAnnotationType(); 2136 } 2137 public Map<Class<? extends Annotation>, Annotation> getDeclaredAnnotationMap(Class<?> klass) { 2138 return klass.getDeclaredAnnotationMap(); 2139 } 2140 public byte[] getRawClassAnnotations(Class<?> klass) { 2141 return klass.getRawAnnotations(); 2142 } 2143 public byte[] getRawClassTypeAnnotations(Class<?> klass) { 2144 return klass.getRawTypeAnnotations(); 2145 } 2146 public byte[] getRawExecutableTypeAnnotations(Executable executable) { 2147 return Class.getExecutableTypeAnnotationBytes(executable); 2148 } 2149 public <E extends Enum<E>> 2150 E[] getEnumConstantsShared(Class<E> klass) { 2151 return klass.getEnumConstantsShared(); 2152 } 2153 public void blockedOn(Interruptible b) { 2154 Thread.blockedOn(b); 2155 } 2156 public void registerShutdownHook(int slot, boolean registerShutdownInProgress, Runnable hook) { 2157 Shutdown.add(slot, registerShutdownInProgress, hook); 2158 } 2159 public Thread newThreadWithAcc(Runnable target, AccessControlContext acc) { 2160 return new Thread(target, acc); 2161 } 2162 @SuppressWarnings("deprecation") 2163 public void invokeFinalize(Object o) throws Throwable { 2164 o.finalize(); 2165 } 2166 public ConcurrentHashMap<?, ?> createOrGetClassLoaderValueMap(ClassLoader cl) { 2167 return cl.createOrGetClassLoaderValueMap(); 2168 } 2169 public Class<?> defineClass(ClassLoader loader, String name, byte[] b, ProtectionDomain pd, String source) { 2170 return ClassLoader.defineClass1(loader, name, b, 0, b.length, pd, source); 2171 } 2172 public Class<?> findBootstrapClassOrNull(ClassLoader cl, String name) { 2173 return cl.findBootstrapClassOrNull(name); 2174 } 2175 public Package definePackage(ClassLoader cl, String name, Module module) { 2176 return cl.definePackage(name, module); 2177 } 2178 public String fastUUID(long lsb, long msb) { 2179 return Long.fastUUID(lsb, msb); 2180 } 2181 public void addNonExportedPackages(ModuleLayer layer) { 2182 SecurityManager.addNonExportedPackages(layer); 2183 } 2184 public void invalidatePackageAccessCache() { 2185 SecurityManager.invalidatePackageAccessCache(); 2186 } 2187 public Module defineModule(ClassLoader loader, 2188 ModuleDescriptor descriptor, 2189 URI uri) { 2190 return new Module(null, loader, descriptor, uri); 2191 } 2192 public Module defineUnnamedModule(ClassLoader loader) { 2193 return new Module(loader); 2194 } 2195 public void addReads(Module m1, Module m2) { 2196 m1.implAddReads(m2); 2197 } 2198 public void addReadsAllUnnamed(Module m) { 2199 m.implAddReadsAllUnnamed(); 2200 } 2201 public void addExports(Module m, String pn, Module other) { 2202 m.implAddExports(pn, other); 2203 } 2204 public void addExportsToAllUnnamed(Module m, String pn) { 2205 m.implAddExportsToAllUnnamed(pn); 2206 } 2207 public void addOpens(Module m, String pn, Module other) { 2208 m.implAddOpens(pn, other); 2209 } 2210 public void addOpensToAllUnnamed(Module m, String pn) { 2211 m.implAddOpensToAllUnnamed(pn); 2212 } 2213 public void addOpensToAllUnnamed(Module m, Iterator<String> packages) { 2214 m.implAddOpensToAllUnnamed(packages); 2215 } 2216 public void addUses(Module m, Class<?> service) { 2217 m.implAddUses(service); 2218 } 2219 public boolean isReflectivelyExported(Module m, String pn, Module other) { 2220 return m.isReflectivelyExported(pn, other); 2221 } 2222 public boolean isReflectivelyOpened(Module m, String pn, Module other) { 2223 return m.isReflectivelyOpened(pn, other); 2224 } 2225 public ServicesCatalog getServicesCatalog(ModuleLayer layer) { 2226 return layer.getServicesCatalog(); 2227 } 2228 public Stream<ModuleLayer> layers(ModuleLayer layer) { 2229 return layer.layers(); 2230 } 2231 public Stream<ModuleLayer> layers(ClassLoader loader) { 2232 return ModuleLayer.layers(loader); 2233 } 2234 2235 public String newStringNoRepl(byte[] bytes, Charset cs) throws CharacterCodingException { 2236 return StringCoding.newStringNoRepl(bytes, cs); 2237 } 2238 2239 public byte[] getBytesNoRepl(String s, Charset cs) throws CharacterCodingException { 2240 return StringCoding.getBytesNoRepl(s, cs); 2241 } 2242 2243 public String newStringUTF8NoRepl(byte[] bytes, int off, int len) { 2244 return StringCoding.newStringUTF8NoRepl(bytes, off, len); 2245 } 2246 2247 public byte[] getBytesUTF8NoRepl(String s) { 2248 return StringCoding.getBytesUTF8NoRepl(s); 2249 } 2250 2251 public void setCause(Throwable t, Throwable cause) { 2252 t.setCause(cause); 2253 } 2254 }); 2255 } 2256 }