1 /* 2 * Copyright (c) 1994, 2019, 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.io; 27 28 import java.net.URI; 29 import java.net.URL; 30 import java.net.MalformedURLException; 31 import java.net.URISyntaxException; 32 import java.nio.file.FileSystems; 33 import java.nio.file.Path; 34 import java.security.SecureRandom; 35 import java.util.ArrayList; 36 import java.util.List; 37 import sun.security.action.GetPropertyAction; 38 39 /** 40 * An abstract representation of file and directory pathnames. 41 * 42 * <p> User interfaces and operating systems use system-dependent <em>pathname 43 * strings</em> to name files and directories. This class presents an 44 * abstract, system-independent view of hierarchical pathnames. An 45 * <em>abstract pathname</em> has two components: 46 * 47 * <ol> 48 * <li> An optional system-dependent <em>prefix</em> string, 49 * such as a disk-drive specifier, <code>"/"</code> for the UNIX root 50 * directory, or <code>"\\\\"</code> for a Microsoft Windows UNC pathname, and 51 * <li> A sequence of zero or more string <em>names</em>. 52 * </ol> 53 * 54 * The first name in an abstract pathname may be a directory name or, in the 55 * case of Microsoft Windows UNC pathnames, a hostname. Each subsequent name 56 * in an abstract pathname denotes a directory; the last name may denote 57 * either a directory or a file. The <em>empty</em> abstract pathname has no 58 * prefix and an empty name sequence. 59 * 60 * <p> The conversion of a pathname string to or from an abstract pathname is 61 * inherently system-dependent. When an abstract pathname is converted into a 62 * pathname string, each name is separated from the next by a single copy of 63 * the default <em>separator character</em>. The default name-separator 64 * character is defined by the system property <code>file.separator</code>, and 65 * is made available in the public static fields {@link 66 * #separator} and {@link #separatorChar} of this class. 67 * When a pathname string is converted into an abstract pathname, the names 68 * within it may be separated by the default name-separator character or by any 69 * other name-separator character that is supported by the underlying system. 70 * 71 * <p> A pathname, whether abstract or in string form, may be either 72 * <em>absolute</em> or <em>relative</em>. An absolute pathname is complete in 73 * that no other information is required in order to locate the file that it 74 * denotes. A relative pathname, in contrast, must be interpreted in terms of 75 * information taken from some other pathname. By default the classes in the 76 * <code>java.io</code> package always resolve relative pathnames against the 77 * current user directory. This directory is named by the system property 78 * <code>user.dir</code>, and is typically the directory in which the Java 79 * virtual machine was invoked. 80 * 81 * <p> The <em>parent</em> of an abstract pathname may be obtained by invoking 82 * the {@link #getParent} method of this class and consists of the pathname's 83 * prefix and each name in the pathname's name sequence except for the last. 84 * Each directory's absolute pathname is an ancestor of any {@code File} 85 * object with an absolute abstract pathname which begins with the directory's 86 * absolute pathname. For example, the directory denoted by the abstract 87 * pathname {@code "/usr"} is an ancestor of the directory denoted by the 88 * pathname {@code "/usr/local/bin"}. 89 * 90 * <p> The prefix concept is used to handle root directories on UNIX platforms, 91 * and drive specifiers, root directories and UNC pathnames on Microsoft Windows platforms, 92 * as follows: 93 * 94 * <ul> 95 * 96 * <li> For UNIX platforms, the prefix of an absolute pathname is always 97 * <code>"/"</code>. Relative pathnames have no prefix. The abstract pathname 98 * denoting the root directory has the prefix <code>"/"</code> and an empty 99 * name sequence. 100 * 101 * <li> For Microsoft Windows platforms, the prefix of a pathname that contains a drive 102 * specifier consists of the drive letter followed by <code>":"</code> and 103 * possibly followed by <code>"\\"</code> if the pathname is absolute. The 104 * prefix of a UNC pathname is <code>"\\\\"</code>; the hostname and the share 105 * name are the first two names in the name sequence. A relative pathname that 106 * does not specify a drive has no prefix. 107 * 108 * </ul> 109 * 110 * <p> Instances of this class may or may not denote an actual file-system 111 * object such as a file or a directory. If it does denote such an object 112 * then that object resides in a <i>partition</i>. A partition is an 113 * operating system-specific portion of storage for a file system. A single 114 * storage device (e.g. a physical disk-drive, flash memory, CD-ROM) may 115 * contain multiple partitions. The object, if any, will reside on the 116 * partition <a id="partName">named</a> by some ancestor of the absolute 117 * form of this pathname. 118 * 119 * <p> A file system may implement restrictions to certain operations on the 120 * actual file-system object, such as reading, writing, and executing. These 121 * restrictions are collectively known as <i>access permissions</i>. The file 122 * system may have multiple sets of access permissions on a single object. 123 * For example, one set may apply to the object's <i>owner</i>, and another 124 * may apply to all other users. The access permissions on an object may 125 * cause some methods in this class to fail. 126 * 127 * <p> Instances of the <code>File</code> class are immutable; that is, once 128 * created, the abstract pathname represented by a <code>File</code> object 129 * will never change. 130 * 131 * <h2>Interoperability with {@code java.nio.file} package</h2> 132 * 133 * <p> The <a href="../../java/nio/file/package-summary.html">{@code java.nio.file}</a> 134 * package defines interfaces and classes for the Java virtual machine to access 135 * files, file attributes, and file systems. This API may be used to overcome 136 * many of the limitations of the {@code java.io.File} class. 137 * The {@link #toPath toPath} method may be used to obtain a {@link 138 * Path} that uses the abstract path represented by a {@code File} object to 139 * locate a file. The resulting {@code Path} may be used with the {@link 140 * java.nio.file.Files} class to provide more efficient and extensive access to 141 * additional file operations, file attributes, and I/O exceptions to help 142 * diagnose errors when an operation on a file fails. 143 * 144 * @author unascribed 145 * @since 1.0 146 */ 147 148 public class File 149 implements Serializable, Comparable<File> 150 { 151 152 /** 153 * The FileSystem object representing the platform's local file system. 154 */ 155 private static final FileSystem fs = DefaultFileSystem.getFileSystem(); 156 157 /** 158 * This abstract pathname's normalized pathname string. A normalized 159 * pathname string uses the default name-separator character and does not 160 * contain any duplicate or redundant separators. 161 * 162 * @serial 163 */ 164 private final String path; 165 166 /** 167 * Enum type that indicates the status of a file path. 168 */ 169 private static enum PathStatus { INVALID, CHECKED }; 170 171 /** 172 * The flag indicating whether the file path is invalid. 173 */ 174 private transient PathStatus status = null; 175 176 /** 177 * Check if the file has an invalid path. Currently, the inspection of 178 * a file path is very limited, and it only covers Nul character check. 179 * Returning true means the path is definitely invalid/garbage. But 180 * returning false does not guarantee that the path is valid. 181 * 182 * @return true if the file path is invalid. 183 */ 184 final boolean isInvalid() { 185 if (status == null) { 186 status = (this.path.indexOf('\u0000') < 0) ? PathStatus.CHECKED 187 : PathStatus.INVALID; 188 } 189 return status == PathStatus.INVALID; 190 } 191 192 /** 193 * The length of this abstract pathname's prefix, or zero if it has no 194 * prefix. 195 */ 196 private final transient int prefixLength; 197 198 /** 199 * Returns the length of this abstract pathname's prefix. 200 * For use by FileSystem classes. 201 */ 202 int getPrefixLength() { 203 return prefixLength; 204 } 205 206 /** 207 * The system-dependent default name-separator character. This field is 208 * initialized to contain the first character of the value of the system 209 * property <code>file.separator</code>. On UNIX systems the value of this 210 * field is <code>'/'</code>; on Microsoft Windows systems it is <code>'\\'</code>. 211 * 212 * @see java.lang.System#getProperty(java.lang.String) 213 */ 214 public static final char separatorChar = fs.getSeparator(); 215 216 /** 217 * The system-dependent default name-separator character, represented as a 218 * string for convenience. This string contains a single character, namely 219 * {@link #separatorChar}. 220 */ 221 public static final String separator = "" + separatorChar; 222 223 /** 224 * The system-dependent path-separator character. This field is 225 * initialized to contain the first character of the value of the system 226 * property <code>path.separator</code>. This character is used to 227 * separate filenames in a sequence of files given as a <em>path list</em>. 228 * On UNIX systems, this character is <code>':'</code>; on Microsoft Windows systems it 229 * is <code>';'</code>. 230 * 231 * @see java.lang.System#getProperty(java.lang.String) 232 */ 233 public static final char pathSeparatorChar = fs.getPathSeparator(); 234 235 /** 236 * The system-dependent path-separator character, represented as a string 237 * for convenience. This string contains a single character, namely 238 * {@link #pathSeparatorChar}. 239 */ 240 public static final String pathSeparator = "" + pathSeparatorChar; 241 242 243 /* -- Constructors -- */ 244 245 /** 246 * Internal constructor for already-normalized pathname strings. 247 */ 248 private File(String pathname, int prefixLength) { 249 this.path = pathname; 250 this.prefixLength = prefixLength; 251 } 252 253 /** 254 * Internal constructor for already-normalized pathname strings. 255 * The parameter order is used to disambiguate this method from the 256 * public(File, String) constructor. 257 */ 258 private File(String child, File parent) { 259 assert parent.path != null; 260 assert (!parent.path.isEmpty()); 261 this.path = fs.resolve(parent.path, child); 262 this.prefixLength = parent.prefixLength; 263 } 264 265 /** 266 * Creates a new <code>File</code> instance by converting the given 267 * pathname string into an abstract pathname. If the given string is 268 * the empty string, then the result is the empty abstract pathname. 269 * 270 * @param pathname A pathname string 271 * @throws NullPointerException 272 * If the <code>pathname</code> argument is <code>null</code> 273 */ 274 public File(String pathname) { 275 if (pathname == null) { 276 throw new NullPointerException(); 277 } 278 this.path = fs.normalize(pathname); 279 this.prefixLength = fs.prefixLength(this.path); 280 } 281 282 /* Note: The two-argument File constructors do not interpret an empty 283 parent abstract pathname as the current user directory. An empty parent 284 instead causes the child to be resolved against the system-dependent 285 directory defined by the FileSystem.getDefaultParent method. On Unix 286 this default is "/", while on Microsoft Windows it is "\\". This is required for 287 compatibility with the original behavior of this class. */ 288 289 /** 290 * Creates a new <code>File</code> instance from a parent pathname string 291 * and a child pathname string. 292 * 293 * <p> If <code>parent</code> is <code>null</code> then the new 294 * <code>File</code> instance is created as if by invoking the 295 * single-argument <code>File</code> constructor on the given 296 * <code>child</code> pathname string. 297 * 298 * <p> Otherwise the <code>parent</code> pathname string is taken to denote 299 * a directory, and the <code>child</code> pathname string is taken to 300 * denote either a directory or a file. If the <code>child</code> pathname 301 * string is absolute then it is converted into a relative pathname in a 302 * system-dependent way. If <code>parent</code> is the empty string then 303 * the new <code>File</code> instance is created by converting 304 * <code>child</code> into an abstract pathname and resolving the result 305 * against a system-dependent default directory. Otherwise each pathname 306 * string is converted into an abstract pathname and the child abstract 307 * pathname is resolved against the parent. 308 * 309 * @param parent The parent pathname string 310 * @param child The child pathname string 311 * @throws NullPointerException 312 * If <code>child</code> is <code>null</code> 313 */ 314 public File(String parent, String child) { 315 if (child == null) { 316 throw new NullPointerException(); 317 } 318 if (parent != null) { 319 if (parent.isEmpty()) { 320 this.path = fs.resolve(fs.getDefaultParent(), 321 fs.normalize(child)); 322 } else { 323 this.path = fs.resolve(fs.normalize(parent), 324 fs.normalize(child)); 325 } 326 } else { 327 this.path = fs.normalize(child); 328 } 329 this.prefixLength = fs.prefixLength(this.path); 330 } 331 332 /** 333 * Creates a new <code>File</code> instance from a parent abstract 334 * pathname and a child pathname string. 335 * 336 * <p> If <code>parent</code> is <code>null</code> then the new 337 * <code>File</code> instance is created as if by invoking the 338 * single-argument <code>File</code> constructor on the given 339 * <code>child</code> pathname string. 340 * 341 * <p> Otherwise the <code>parent</code> abstract pathname is taken to 342 * denote a directory, and the <code>child</code> pathname string is taken 343 * to denote either a directory or a file. If the <code>child</code> 344 * pathname string is absolute then it is converted into a relative 345 * pathname in a system-dependent way. If <code>parent</code> is the empty 346 * abstract pathname then the new <code>File</code> instance is created by 347 * converting <code>child</code> into an abstract pathname and resolving 348 * the result against a system-dependent default directory. Otherwise each 349 * pathname string is converted into an abstract pathname and the child 350 * abstract pathname is resolved against the parent. 351 * 352 * @param parent The parent abstract pathname 353 * @param child The child pathname string 354 * @throws NullPointerException 355 * If <code>child</code> is <code>null</code> 356 */ 357 public File(File parent, String child) { 358 if (child == null) { 359 throw new NullPointerException(); 360 } 361 if (parent != null) { 362 if (parent.path.isEmpty()) { 363 this.path = fs.resolve(fs.getDefaultParent(), 364 fs.normalize(child)); 365 } else { 366 this.path = fs.resolve(parent.path, 367 fs.normalize(child)); 368 } 369 } else { 370 this.path = fs.normalize(child); 371 } 372 this.prefixLength = fs.prefixLength(this.path); 373 } 374 375 /** 376 * Creates a new {@code File} instance by converting the given 377 * {@code file:} URI into an abstract pathname. 378 * 379 * <p> The exact form of a {@code file:} URI is system-dependent, hence 380 * the transformation performed by this constructor is also 381 * system-dependent. 382 * 383 * <p> For a given abstract pathname <i>f</i> it is guaranteed that 384 * 385 * <blockquote><code> 386 * new File(</code><i> f</i><code>.{@link #toURI() 387 * toURI}()).equals(</code><i> f</i><code>.{@link #getAbsoluteFile() getAbsoluteFile}()) 388 * </code></blockquote> 389 * 390 * so long as the original abstract pathname, the URI, and the new abstract 391 * pathname are all created in (possibly different invocations of) the same 392 * Java virtual machine. This relationship typically does not hold, 393 * however, when a {@code file:} URI that is created in a virtual machine 394 * on one operating system is converted into an abstract pathname in a 395 * virtual machine on a different operating system. 396 * 397 * @param uri 398 * An absolute, hierarchical URI with a scheme equal to 399 * {@code "file"}, a non-empty path component, and undefined 400 * authority, query, and fragment components 401 * 402 * @throws NullPointerException 403 * If {@code uri} is {@code null} 404 * 405 * @throws IllegalArgumentException 406 * If the preconditions on the parameter do not hold 407 * 408 * @see #toURI() 409 * @see java.net.URI 410 * @since 1.4 411 */ 412 public File(URI uri) { 413 414 // Check our many preconditions 415 if (!uri.isAbsolute()) 416 throw new IllegalArgumentException("URI is not absolute"); 417 if (uri.isOpaque()) 418 throw new IllegalArgumentException("URI is not hierarchical"); 419 String scheme = uri.getScheme(); 420 if ((scheme == null) || !scheme.equalsIgnoreCase("file")) 421 throw new IllegalArgumentException("URI scheme is not \"file\""); 422 if (uri.getRawAuthority() != null) 423 throw new IllegalArgumentException("URI has an authority component"); 424 if (uri.getRawFragment() != null) 425 throw new IllegalArgumentException("URI has a fragment component"); 426 if (uri.getRawQuery() != null) 427 throw new IllegalArgumentException("URI has a query component"); 428 String p = uri.getPath(); 429 if (p.isEmpty()) 430 throw new IllegalArgumentException("URI path component is empty"); 431 432 // Okay, now initialize 433 p = fs.fromURIPath(p); 434 if (File.separatorChar != '/') 435 p = p.replace('/', File.separatorChar); 436 this.path = fs.normalize(p); 437 this.prefixLength = fs.prefixLength(this.path); 438 } 439 440 441 /* -- Path-component accessors -- */ 442 443 /** 444 * Returns the name of the file or directory denoted by this abstract 445 * pathname. This is just the last name in the pathname's name 446 * sequence. If the pathname's name sequence is empty, then the empty 447 * string is returned. 448 * 449 * @return The name of the file or directory denoted by this abstract 450 * pathname, or the empty string if this pathname's name sequence 451 * is empty 452 */ 453 public String getName() { 454 int index = path.lastIndexOf(separatorChar); 455 if (index < prefixLength) return path.substring(prefixLength); 456 return path.substring(index + 1); 457 } 458 459 /** 460 * Returns the pathname string of this abstract pathname's parent, or 461 * <code>null</code> if this pathname does not name a parent directory. 462 * 463 * <p> The <em>parent</em> of an abstract pathname consists of the 464 * pathname's prefix, if any, and each name in the pathname's name 465 * sequence except for the last. If the name sequence is empty then 466 * the pathname does not name a parent directory. 467 * 468 * @return The pathname string of the parent directory named by this 469 * abstract pathname, or <code>null</code> if this pathname 470 * does not name a parent 471 */ 472 public String getParent() { 473 int index = path.lastIndexOf(separatorChar); 474 if (index < prefixLength) { 475 if ((prefixLength > 0) && (path.length() > prefixLength)) 476 return path.substring(0, prefixLength); 477 return null; 478 } 479 return path.substring(0, index); 480 } 481 482 /** 483 * Returns the abstract pathname of this abstract pathname's parent, 484 * or <code>null</code> if this pathname does not name a parent 485 * directory. 486 * 487 * <p> The <em>parent</em> of an abstract pathname consists of the 488 * pathname's prefix, if any, and each name in the pathname's name 489 * sequence except for the last. If the name sequence is empty then 490 * the pathname does not name a parent directory. 491 * 492 * @return The abstract pathname of the parent directory named by this 493 * abstract pathname, or <code>null</code> if this pathname 494 * does not name a parent 495 * 496 * @since 1.2 497 */ 498 public File getParentFile() { 499 String p = this.getParent(); 500 if (p == null) return null; 501 return new File(p, this.prefixLength); 502 } 503 504 /** 505 * Converts this abstract pathname into a pathname string. The resulting 506 * string uses the {@link #separator default name-separator character} to 507 * separate the names in the name sequence. 508 * 509 * @return The string form of this abstract pathname 510 */ 511 public String getPath() { 512 return path; 513 } 514 515 516 /* -- Path operations -- */ 517 518 /** 519 * Tests whether this abstract pathname is absolute. The definition of 520 * absolute pathname is system dependent. On UNIX systems, a pathname is 521 * absolute if its prefix is <code>"/"</code>. On Microsoft Windows systems, a 522 * pathname is absolute if its prefix is a drive specifier followed by 523 * <code>"\\"</code>, or if its prefix is <code>"\\\\"</code>. 524 * 525 * @return <code>true</code> if this abstract pathname is absolute, 526 * <code>false</code> otherwise 527 */ 528 public boolean isAbsolute() { 529 return fs.isAbsolute(this); 530 } 531 532 /** 533 * Returns the absolute pathname string of this abstract pathname. 534 * 535 * <p> If this abstract pathname is already absolute, then the pathname 536 * string is simply returned as if by the {@link #getPath} 537 * method. If this abstract pathname is the empty abstract pathname then 538 * the pathname string of the current user directory, which is named by the 539 * system property <code>user.dir</code>, is returned. Otherwise this 540 * pathname is resolved in a system-dependent way. On UNIX systems, a 541 * relative pathname is made absolute by resolving it against the current 542 * user directory. On Microsoft Windows systems, a relative pathname is made absolute 543 * by resolving it against the current directory of the drive named by the 544 * pathname, if any; if not, it is resolved against the current user 545 * directory. 546 * 547 * @return The absolute pathname string denoting the same file or 548 * directory as this abstract pathname 549 * 550 * @throws SecurityException 551 * If a required system property value cannot be accessed. 552 * 553 * @see java.io.File#isAbsolute() 554 */ 555 public String getAbsolutePath() { 556 return fs.resolve(this); 557 } 558 559 /** 560 * Returns the absolute form of this abstract pathname. Equivalent to 561 * <code>new File(this.{@link #getAbsolutePath})</code>. 562 * 563 * @return The absolute abstract pathname denoting the same file or 564 * directory as this abstract pathname 565 * 566 * @throws SecurityException 567 * If a required system property value cannot be accessed. 568 * 569 * @since 1.2 570 */ 571 public File getAbsoluteFile() { 572 String absPath = getAbsolutePath(); 573 return new File(absPath, fs.prefixLength(absPath)); 574 } 575 576 /** 577 * Returns the canonical pathname string of this abstract pathname. 578 * 579 * <p> A canonical pathname is both absolute and unique. The precise 580 * definition of canonical form is system-dependent. This method first 581 * converts this pathname to absolute form if necessary, as if by invoking the 582 * {@link #getAbsolutePath} method, and then maps it to its unique form in a 583 * system-dependent way. This typically involves removing redundant names 584 * such as {@code "."} and {@code ".."} from the pathname, resolving 585 * symbolic links (on UNIX platforms), and converting drive letters to a 586 * standard case (on Microsoft Windows platforms). 587 * 588 * <p> Every pathname that denotes an existing file or directory has a 589 * unique canonical form. Every pathname that denotes a nonexistent file 590 * or directory also has a unique canonical form. The canonical form of 591 * the pathname of a nonexistent file or directory may be different from 592 * the canonical form of the same pathname after the file or directory is 593 * created. Similarly, the canonical form of the pathname of an existing 594 * file or directory may be different from the canonical form of the same 595 * pathname after the file or directory is deleted. 596 * 597 * @return The canonical pathname string denoting the same file or 598 * directory as this abstract pathname 599 * 600 * @throws IOException 601 * If an I/O error occurs, which is possible because the 602 * construction of the canonical pathname may require 603 * filesystem queries 604 * 605 * @throws SecurityException 606 * If a required system property value cannot be accessed, or 607 * if a security manager exists and its {@link 608 * java.lang.SecurityManager#checkRead} method denies 609 * read access to the file 610 * 611 * @since 1.1 612 * @see Path#toRealPath 613 */ 614 public String getCanonicalPath() throws IOException { 615 if (isInvalid()) { 616 throw new IOException("Invalid file path"); 617 } 618 return fs.canonicalize(fs.resolve(this)); 619 } 620 621 /** 622 * Returns the canonical form of this abstract pathname. Equivalent to 623 * <code>new File(this.{@link #getCanonicalPath})</code>. 624 * 625 * @return The canonical pathname string denoting the same file or 626 * directory as this abstract pathname 627 * 628 * @throws IOException 629 * If an I/O error occurs, which is possible because the 630 * construction of the canonical pathname may require 631 * filesystem queries 632 * 633 * @throws SecurityException 634 * If a required system property value cannot be accessed, or 635 * if a security manager exists and its {@link 636 * java.lang.SecurityManager#checkRead} method denies 637 * read access to the file 638 * 639 * @since 1.2 640 * @see Path#toRealPath 641 */ 642 public File getCanonicalFile() throws IOException { 643 String canonPath = getCanonicalPath(); 644 return new File(canonPath, fs.prefixLength(canonPath)); 645 } 646 647 private static String slashify(String path, boolean isDirectory) { 648 String p = path; 649 if (File.separatorChar != '/') 650 p = p.replace(File.separatorChar, '/'); 651 if (!p.startsWith("/")) 652 p = "/" + p; 653 if (!p.endsWith("/") && isDirectory) 654 p = p + "/"; 655 return p; 656 } 657 658 /** 659 * Converts this abstract pathname into a <code>file:</code> URL. The 660 * exact form of the URL is system-dependent. If it can be determined that 661 * the file denoted by this abstract pathname is a directory, then the 662 * resulting URL will end with a slash. 663 * 664 * @return A URL object representing the equivalent file URL 665 * 666 * @throws MalformedURLException 667 * If the path cannot be parsed as a URL 668 * 669 * @see #toURI() 670 * @see java.net.URI 671 * @see java.net.URI#toURL() 672 * @see java.net.URL 673 * @since 1.2 674 * 675 * @deprecated This method does not automatically escape characters that 676 * are illegal in URLs. It is recommended that new code convert an 677 * abstract pathname into a URL by first converting it into a URI, via the 678 * {@link #toURI() toURI} method, and then converting the URI into a URL 679 * via the {@link java.net.URI#toURL() URI.toURL} method. 680 */ 681 @Deprecated 682 public URL toURL() throws MalformedURLException { 683 if (isInvalid()) { 684 throw new MalformedURLException("Invalid file path"); 685 } 686 return new URL("file", "", slashify(getAbsolutePath(), isDirectory())); 687 } 688 689 /** 690 * Constructs a {@code file:} URI that represents this abstract pathname. 691 * 692 * <p> The exact form of the URI is system-dependent. If it can be 693 * determined that the file denoted by this abstract pathname is a 694 * directory, then the resulting URI will end with a slash. 695 * 696 * <p> For a given abstract pathname <i>f</i>, it is guaranteed that 697 * 698 * <blockquote><code> 699 * new {@link #File(java.net.URI) File}(</code><i> f</i><code>.toURI()).equals( 700 * </code><i> f</i><code>.{@link #getAbsoluteFile() getAbsoluteFile}()) 701 * </code></blockquote> 702 * 703 * so long as the original abstract pathname, the URI, and the new abstract 704 * pathname are all created in (possibly different invocations of) the same 705 * Java virtual machine. Due to the system-dependent nature of abstract 706 * pathnames, however, this relationship typically does not hold when a 707 * {@code file:} URI that is created in a virtual machine on one operating 708 * system is converted into an abstract pathname in a virtual machine on a 709 * different operating system. 710 * 711 * <p> Note that when this abstract pathname represents a UNC pathname then 712 * all components of the UNC (including the server name component) are encoded 713 * in the {@code URI} path. The authority component is undefined, meaning 714 * that it is represented as {@code null}. The {@link Path} class defines the 715 * {@link Path#toUri toUri} method to encode the server name in the authority 716 * component of the resulting {@code URI}. The {@link #toPath toPath} method 717 * may be used to obtain a {@code Path} representing this abstract pathname. 718 * 719 * @return An absolute, hierarchical URI with a scheme equal to 720 * {@code "file"}, a path representing this abstract pathname, 721 * and undefined authority, query, and fragment components 722 * @throws SecurityException If a required system property value cannot 723 * be accessed. 724 * 725 * @see #File(java.net.URI) 726 * @see java.net.URI 727 * @see java.net.URI#toURL() 728 * @since 1.4 729 */ 730 public URI toURI() { 731 try { 732 File f = getAbsoluteFile(); 733 String sp = slashify(f.getPath(), f.isDirectory()); 734 if (sp.startsWith("//")) 735 sp = "//" + sp; 736 return new URI("file", null, sp, null); 737 } catch (URISyntaxException x) { 738 throw new Error(x); // Can't happen 739 } 740 } 741 742 743 /* -- Attribute accessors -- */ 744 745 /** 746 * Tests whether the application can read the file denoted by this 747 * abstract pathname. On some platforms it may be possible to start the 748 * Java virtual machine with special privileges that allow it to read 749 * files that are marked as unreadable. Consequently this method may return 750 * {@code true} even though the file does not have read permissions. 751 * 752 * @return <code>true</code> if and only if the file specified by this 753 * abstract pathname exists <em>and</em> can be read by the 754 * application; <code>false</code> otherwise 755 * 756 * @throws SecurityException 757 * If a security manager exists and its {@link 758 * java.lang.SecurityManager#checkRead(java.lang.String)} 759 * method denies read access to the file 760 */ 761 public boolean canRead() { 762 SecurityManager security = System.getSecurityManager(); 763 if (security != null) { 764 security.checkRead(path); 765 } 766 if (isInvalid()) { 767 return false; 768 } 769 return fs.checkAccess(this, FileSystem.ACCESS_READ); 770 } 771 772 /** 773 * Tests whether the application can modify the file denoted by this 774 * abstract pathname. On some platforms it may be possible to start the 775 * Java virtual machine with special privileges that allow it to modify 776 * files that are marked read-only. Consequently this method may return 777 * {@code true} even though the file is marked read-only. 778 * 779 * @return <code>true</code> if and only if the file system actually 780 * contains a file denoted by this abstract pathname <em>and</em> 781 * the application is allowed to write to the file; 782 * <code>false</code> otherwise. 783 * 784 * @throws SecurityException 785 * If a security manager exists and its {@link 786 * java.lang.SecurityManager#checkWrite(java.lang.String)} 787 * method denies write access to the file 788 */ 789 public boolean canWrite() { 790 SecurityManager security = System.getSecurityManager(); 791 if (security != null) { 792 security.checkWrite(path); 793 } 794 if (isInvalid()) { 795 return false; 796 } 797 return fs.checkAccess(this, FileSystem.ACCESS_WRITE); 798 } 799 800 /** 801 * Tests whether the file or directory denoted by this abstract pathname 802 * exists. 803 * 804 * @return <code>true</code> if and only if the file or directory denoted 805 * by this abstract pathname exists; <code>false</code> otherwise 806 * 807 * @throws SecurityException 808 * If a security manager exists and its {@link 809 * java.lang.SecurityManager#checkRead(java.lang.String)} 810 * method denies read access to the file or directory 811 */ 812 public boolean exists() { 813 SecurityManager security = System.getSecurityManager(); 814 if (security != null) { 815 security.checkRead(path); 816 } 817 if (isInvalid()) { 818 return false; 819 } 820 return ((fs.getBooleanAttributes(this) & FileSystem.BA_EXISTS) != 0); 821 } 822 823 /** 824 * Tests whether the file denoted by this abstract pathname is a 825 * directory. 826 * 827 * <p> Where it is required to distinguish an I/O exception from the case 828 * that the file is not a directory, or where several attributes of the 829 * same file are required at the same time, then the {@link 830 * java.nio.file.Files#readAttributes(Path,Class,LinkOption[]) 831 * Files.readAttributes} method may be used. 832 * 833 * @return <code>true</code> if and only if the file denoted by this 834 * abstract pathname exists <em>and</em> is a directory; 835 * <code>false</code> otherwise 836 * 837 * @throws SecurityException 838 * If a security manager exists and its {@link 839 * java.lang.SecurityManager#checkRead(java.lang.String)} 840 * method denies read access to the file 841 */ 842 public boolean isDirectory() { 843 SecurityManager security = System.getSecurityManager(); 844 if (security != null) { 845 security.checkRead(path); 846 } 847 if (isInvalid()) { 848 return false; 849 } 850 return ((fs.getBooleanAttributes(this) & FileSystem.BA_DIRECTORY) 851 != 0); 852 } 853 854 /** 855 * Tests whether the file denoted by this abstract pathname is a normal 856 * file. A file is <em>normal</em> if it is not a directory and, in 857 * addition, satisfies other system-dependent criteria. Any non-directory 858 * file created by a Java application is guaranteed to be a normal file. 859 * 860 * <p> Where it is required to distinguish an I/O exception from the case 861 * that the file is not a normal file, or where several attributes of the 862 * same file are required at the same time, then the {@link 863 * java.nio.file.Files#readAttributes(Path,Class,LinkOption[]) 864 * Files.readAttributes} method may be used. 865 * 866 * @return <code>true</code> if and only if the file denoted by this 867 * abstract pathname exists <em>and</em> is a normal file; 868 * <code>false</code> otherwise 869 * 870 * @throws SecurityException 871 * If a security manager exists and its {@link 872 * java.lang.SecurityManager#checkRead(java.lang.String)} 873 * method denies read access to the file 874 */ 875 public boolean isFile() { 876 SecurityManager security = System.getSecurityManager(); 877 if (security != null) { 878 security.checkRead(path); 879 } 880 if (isInvalid()) { 881 return false; 882 } 883 return ((fs.getBooleanAttributes(this) & FileSystem.BA_REGULAR) != 0); 884 } 885 886 /** 887 * Tests whether the file named by this abstract pathname is a hidden 888 * file. The exact definition of <em>hidden</em> is system-dependent. On 889 * UNIX systems, a file is considered to be hidden if its name begins with 890 * a period character (<code>'.'</code>). On Microsoft Windows systems, a file is 891 * considered to be hidden if it has been marked as such in the filesystem. 892 * 893 * @return <code>true</code> if and only if the file denoted by this 894 * abstract pathname is hidden according to the conventions of the 895 * underlying platform 896 * 897 * @throws SecurityException 898 * If a security manager exists and its {@link 899 * java.lang.SecurityManager#checkRead(java.lang.String)} 900 * method denies read access to the file 901 * 902 * @since 1.2 903 */ 904 public boolean isHidden() { 905 SecurityManager security = System.getSecurityManager(); 906 if (security != null) { 907 security.checkRead(path); 908 } 909 if (isInvalid()) { 910 return false; 911 } 912 return ((fs.getBooleanAttributes(this) & FileSystem.BA_HIDDEN) != 0); 913 } 914 915 /** 916 * Returns the time that the file denoted by this abstract pathname was 917 * last modified. 918 * 919 * @apiNote 920 * While the unit of time of the return value is milliseconds, the 921 * granularity of the value depends on the underlying file system and may 922 * be larger. For example, some file systems use time stamps in units of 923 * seconds. 924 * 925 * <p> Where it is required to distinguish an I/O exception from the case 926 * where {@code 0L} is returned, or where several attributes of the 927 * same file are required at the same time, or where the time of last 928 * access or the creation time are required, then the {@link 929 * java.nio.file.Files#readAttributes(Path,Class,LinkOption[]) 930 * Files.readAttributes} method may be used. If however only the 931 * time of last modification is required, then the 932 * {@link java.nio.file.Files#getLastModifiedTime(Path,LinkOption[]) 933 * Files.getLastModifiedTime} method may be used instead. 934 * 935 * @return A <code>long</code> value representing the time the file was 936 * last modified, measured in milliseconds since the epoch 937 * (00:00:00 GMT, January 1, 1970), or <code>0L</code> if the 938 * file does not exist or if an I/O error occurs. The value may 939 * be negative indicating the number of milliseconds before the 940 * epoch 941 * 942 * @throws SecurityException 943 * If a security manager exists and its {@link 944 * java.lang.SecurityManager#checkRead(java.lang.String)} 945 * method denies read access to the file 946 */ 947 public long lastModified() { 948 SecurityManager security = System.getSecurityManager(); 949 if (security != null) { 950 security.checkRead(path); 951 } 952 if (isInvalid()) { 953 return 0L; 954 } 955 return fs.getLastModifiedTime(this); 956 } 957 958 /** 959 * Returns the length of the file denoted by this abstract pathname. 960 * The return value is unspecified if this pathname denotes a directory. 961 * 962 * <p> Where it is required to distinguish an I/O exception from the case 963 * that {@code 0L} is returned, or where several attributes of the same file 964 * are required at the same time, then the {@link 965 * java.nio.file.Files#readAttributes(Path,Class,LinkOption[]) 966 * Files.readAttributes} method may be used. 967 * 968 * @return The length, in bytes, of the file denoted by this abstract 969 * pathname, or <code>0L</code> if the file does not exist. Some 970 * operating systems may return <code>0L</code> for pathnames 971 * denoting system-dependent entities such as devices or pipes. 972 * 973 * @throws SecurityException 974 * If a security manager exists and its {@link 975 * java.lang.SecurityManager#checkRead(java.lang.String)} 976 * method denies read access to the file 977 */ 978 public long length() { 979 SecurityManager security = System.getSecurityManager(); 980 if (security != null) { 981 security.checkRead(path); 982 } 983 if (isInvalid()) { 984 return 0L; 985 } 986 return fs.getLength(this); 987 } 988 989 990 /* -- File operations -- */ 991 992 /** 993 * Atomically creates a new, empty file named by this abstract pathname if 994 * and only if a file with this name does not yet exist. The check for the 995 * existence of the file and the creation of the file if it does not exist 996 * are a single operation that is atomic with respect to all other 997 * filesystem activities that might affect the file. 998 * <P> 999 * Note: this method should <i>not</i> be used for file-locking, as 1000 * the resulting protocol cannot be made to work reliably. The 1001 * {@link java.nio.channels.FileLock FileLock} 1002 * facility should be used instead. 1003 * 1004 * @return <code>true</code> if the named file does not exist and was 1005 * successfully created; <code>false</code> if the named file 1006 * already exists 1007 * 1008 * @throws IOException 1009 * If an I/O error occurred 1010 * 1011 * @throws SecurityException 1012 * If a security manager exists and its {@link 1013 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1014 * method denies write access to the file 1015 * 1016 * @since 1.2 1017 */ 1018 public boolean createNewFile() throws IOException { 1019 SecurityManager security = System.getSecurityManager(); 1020 if (security != null) security.checkWrite(path); 1021 if (isInvalid()) { 1022 throw new IOException("Invalid file path"); 1023 } 1024 return fs.createFileExclusively(path); 1025 } 1026 1027 /** 1028 * Deletes the file or directory denoted by this abstract pathname. If 1029 * this pathname denotes a directory, then the directory must be empty in 1030 * order to be deleted. 1031 * 1032 * <p> Note that the {@link java.nio.file.Files} class defines the {@link 1033 * java.nio.file.Files#delete(Path) delete} method to throw an {@link IOException} 1034 * when a file cannot be deleted. This is useful for error reporting and to 1035 * diagnose why a file cannot be deleted. 1036 * 1037 * @return <code>true</code> if and only if the file or directory is 1038 * successfully deleted; <code>false</code> otherwise 1039 * 1040 * @throws SecurityException 1041 * If a security manager exists and its {@link 1042 * java.lang.SecurityManager#checkDelete} method denies 1043 * delete access to the file 1044 */ 1045 public boolean delete() { 1046 SecurityManager security = System.getSecurityManager(); 1047 if (security != null) { 1048 security.checkDelete(path); 1049 } 1050 if (isInvalid()) { 1051 return false; 1052 } 1053 return fs.delete(this); 1054 } 1055 1056 /** 1057 * Requests that the file or directory denoted by this abstract 1058 * pathname be deleted when the virtual machine terminates. 1059 * Files (or directories) are deleted in the reverse order that 1060 * they are registered. Invoking this method to delete a file or 1061 * directory that is already registered for deletion has no effect. 1062 * Deletion will be attempted only for normal termination of the 1063 * virtual machine, as defined by the Java Language Specification. 1064 * 1065 * <p> Once deletion has been requested, it is not possible to cancel the 1066 * request. This method should therefore be used with care. 1067 * 1068 * <P> 1069 * Note: this method should <i>not</i> be used for file-locking, as 1070 * the resulting protocol cannot be made to work reliably. The 1071 * {@link java.nio.channels.FileLock FileLock} 1072 * facility should be used instead. 1073 * 1074 * @throws SecurityException 1075 * If a security manager exists and its {@link 1076 * java.lang.SecurityManager#checkDelete} method denies 1077 * delete access to the file 1078 * 1079 * @see #delete 1080 * 1081 * @since 1.2 1082 */ 1083 public void deleteOnExit() { 1084 SecurityManager security = System.getSecurityManager(); 1085 if (security != null) { 1086 security.checkDelete(path); 1087 } 1088 if (isInvalid()) { 1089 return; 1090 } 1091 DeleteOnExitHook.add(path); 1092 } 1093 1094 /** 1095 * Returns an array of strings naming the files and directories in the 1096 * directory denoted by this abstract pathname. 1097 * 1098 * <p> If this abstract pathname does not denote a directory, then this 1099 * method returns {@code null}. Otherwise an array of strings is 1100 * returned, one for each file or directory in the directory. Names 1101 * denoting the directory itself and the directory's parent directory are 1102 * not included in the result. Each string is a file name rather than a 1103 * complete path. 1104 * 1105 * <p> There is no guarantee that the name strings in the resulting array 1106 * will appear in any specific order; they are not, in particular, 1107 * guaranteed to appear in alphabetical order. 1108 * 1109 * <p> Note that the {@link java.nio.file.Files} class defines the {@link 1110 * java.nio.file.Files#newDirectoryStream(Path) newDirectoryStream} method to 1111 * open a directory and iterate over the names of the files in the directory. 1112 * This may use less resources when working with very large directories, and 1113 * may be more responsive when working with remote directories. 1114 * 1115 * @return An array of strings naming the files and directories in the 1116 * directory denoted by this abstract pathname. The array will be 1117 * empty if the directory is empty. Returns {@code null} if 1118 * this abstract pathname does not denote a directory, or if an 1119 * I/O error occurs. 1120 * 1121 * @throws SecurityException 1122 * If a security manager exists and its {@link 1123 * SecurityManager#checkRead(String)} method denies read access to 1124 * the directory 1125 */ 1126 public String[] list() { 1127 SecurityManager security = System.getSecurityManager(); 1128 if (security != null) { 1129 security.checkRead(path); 1130 } 1131 if (isInvalid()) { 1132 return null; 1133 } 1134 return fs.list(this); 1135 } 1136 1137 /** 1138 * Returns an array of strings naming the files and directories in the 1139 * directory denoted by this abstract pathname that satisfy the specified 1140 * filter. The behavior of this method is the same as that of the 1141 * {@link #list()} method, except that the strings in the returned array 1142 * must satisfy the filter. If the given {@code filter} is {@code null} 1143 * then all names are accepted. Otherwise, a name satisfies the filter if 1144 * and only if the value {@code true} results when the {@link 1145 * FilenameFilter#accept FilenameFilter.accept(File, String)} method 1146 * of the filter is invoked on this abstract pathname and the name of a 1147 * file or directory in the directory that it denotes. 1148 * 1149 * @param filter 1150 * A filename filter 1151 * 1152 * @return An array of strings naming the files and directories in the 1153 * directory denoted by this abstract pathname that were accepted 1154 * by the given {@code filter}. The array will be empty if the 1155 * directory is empty or if no names were accepted by the filter. 1156 * Returns {@code null} if this abstract pathname does not denote 1157 * a directory, or if an I/O error occurs. 1158 * 1159 * @throws SecurityException 1160 * If a security manager exists and its {@link 1161 * SecurityManager#checkRead(String)} method denies read access to 1162 * the directory 1163 * 1164 * @see java.nio.file.Files#newDirectoryStream(Path,String) 1165 */ 1166 public String[] list(FilenameFilter filter) { 1167 String names[] = list(); 1168 if ((names == null) || (filter == null)) { 1169 return names; 1170 } 1171 List<String> v = new ArrayList<>(); 1172 for (int i = 0 ; i < names.length ; i++) { 1173 if (filter.accept(this, names[i])) { 1174 v.add(names[i]); 1175 } 1176 } 1177 return v.toArray(new String[v.size()]); 1178 } 1179 1180 /** 1181 * Returns an array of abstract pathnames denoting the files in the 1182 * directory denoted by this abstract pathname. 1183 * 1184 * <p> If this abstract pathname does not denote a directory, then this 1185 * method returns {@code null}. Otherwise an array of {@code File} objects 1186 * is returned, one for each file or directory in the directory. Pathnames 1187 * denoting the directory itself and the directory's parent directory are 1188 * not included in the result. Each resulting abstract pathname is 1189 * constructed from this abstract pathname using the {@link #File(File, 1190 * String) File(File, String)} constructor. Therefore if this 1191 * pathname is absolute then each resulting pathname is absolute; if this 1192 * pathname is relative then each resulting pathname will be relative to 1193 * the same directory. 1194 * 1195 * <p> There is no guarantee that the name strings in the resulting array 1196 * will appear in any specific order; they are not, in particular, 1197 * guaranteed to appear in alphabetical order. 1198 * 1199 * <p> Note that the {@link java.nio.file.Files} class defines the {@link 1200 * java.nio.file.Files#newDirectoryStream(Path) newDirectoryStream} method 1201 * to open a directory and iterate over the names of the files in the 1202 * directory. This may use less resources when working with very large 1203 * directories. 1204 * 1205 * @return An array of abstract pathnames denoting the files and 1206 * directories in the directory denoted by this abstract pathname. 1207 * The array will be empty if the directory is empty. Returns 1208 * {@code null} if this abstract pathname does not denote a 1209 * directory, or if an I/O error occurs. 1210 * 1211 * @throws SecurityException 1212 * If a security manager exists and its {@link 1213 * SecurityManager#checkRead(String)} method denies read access to 1214 * the directory 1215 * 1216 * @since 1.2 1217 */ 1218 public File[] listFiles() { 1219 String[] ss = list(); 1220 if (ss == null) return null; 1221 int n = ss.length; 1222 File[] fs = new File[n]; 1223 for (int i = 0; i < n; i++) { 1224 fs[i] = new File(ss[i], this); 1225 } 1226 return fs; 1227 } 1228 1229 /** 1230 * Returns an array of abstract pathnames denoting the files and 1231 * directories in the directory denoted by this abstract pathname that 1232 * satisfy the specified filter. The behavior of this method is the same 1233 * as that of the {@link #listFiles()} method, except that the pathnames in 1234 * the returned array must satisfy the filter. If the given {@code filter} 1235 * is {@code null} then all pathnames are accepted. Otherwise, a pathname 1236 * satisfies the filter if and only if the value {@code true} results when 1237 * the {@link FilenameFilter#accept 1238 * FilenameFilter.accept(File, String)} method of the filter is 1239 * invoked on this abstract pathname and the name of a file or directory in 1240 * the directory that it denotes. 1241 * 1242 * @param filter 1243 * A filename filter 1244 * 1245 * @return An array of abstract pathnames denoting the files and 1246 * directories in the directory denoted by this abstract pathname. 1247 * The array will be empty if the directory is empty. Returns 1248 * {@code null} if this abstract pathname does not denote a 1249 * directory, or if an I/O error occurs. 1250 * 1251 * @throws SecurityException 1252 * If a security manager exists and its {@link 1253 * SecurityManager#checkRead(String)} method denies read access to 1254 * the directory 1255 * 1256 * @since 1.2 1257 * @see java.nio.file.Files#newDirectoryStream(Path,String) 1258 */ 1259 public File[] listFiles(FilenameFilter filter) { 1260 String ss[] = list(); 1261 if (ss == null) return null; 1262 ArrayList<File> files = new ArrayList<>(); 1263 for (String s : ss) 1264 if ((filter == null) || filter.accept(this, s)) 1265 files.add(new File(s, this)); 1266 return files.toArray(new File[files.size()]); 1267 } 1268 1269 /** 1270 * Returns an array of abstract pathnames denoting the files and 1271 * directories in the directory denoted by this abstract pathname that 1272 * satisfy the specified filter. The behavior of this method is the same 1273 * as that of the {@link #listFiles()} method, except that the pathnames in 1274 * the returned array must satisfy the filter. If the given {@code filter} 1275 * is {@code null} then all pathnames are accepted. Otherwise, a pathname 1276 * satisfies the filter if and only if the value {@code true} results when 1277 * the {@link FileFilter#accept FileFilter.accept(File)} method of the 1278 * filter is invoked on the pathname. 1279 * 1280 * @param filter 1281 * A file filter 1282 * 1283 * @return An array of abstract pathnames denoting the files and 1284 * directories in the directory denoted by this abstract pathname. 1285 * The array will be empty if the directory is empty. Returns 1286 * {@code null} if this abstract pathname does not denote a 1287 * directory, or if an I/O error occurs. 1288 * 1289 * @throws SecurityException 1290 * If a security manager exists and its {@link 1291 * SecurityManager#checkRead(String)} method denies read access to 1292 * the directory 1293 * 1294 * @since 1.2 1295 * @see java.nio.file.Files#newDirectoryStream(Path,java.nio.file.DirectoryStream.Filter) 1296 */ 1297 public File[] listFiles(FileFilter filter) { 1298 String ss[] = list(); 1299 if (ss == null) return null; 1300 ArrayList<File> files = new ArrayList<>(); 1301 for (String s : ss) { 1302 File f = new File(s, this); 1303 if ((filter == null) || filter.accept(f)) 1304 files.add(f); 1305 } 1306 return files.toArray(new File[files.size()]); 1307 } 1308 1309 /** 1310 * Creates the directory named by this abstract pathname. 1311 * 1312 * @return <code>true</code> if and only if the directory was 1313 * created; <code>false</code> otherwise 1314 * 1315 * @throws SecurityException 1316 * If a security manager exists and its {@link 1317 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1318 * method does not permit the named directory to be created 1319 */ 1320 public boolean mkdir() { 1321 SecurityManager security = System.getSecurityManager(); 1322 if (security != null) { 1323 security.checkWrite(path); 1324 } 1325 if (isInvalid()) { 1326 return false; 1327 } 1328 return fs.createDirectory(this); 1329 } 1330 1331 /** 1332 * Creates the directory named by this abstract pathname, including any 1333 * necessary but nonexistent parent directories. Note that if this 1334 * operation fails it may have succeeded in creating some of the necessary 1335 * parent directories. 1336 * 1337 * @return <code>true</code> if and only if the directory was created, 1338 * along with all necessary parent directories; <code>false</code> 1339 * otherwise 1340 * 1341 * @throws SecurityException 1342 * If a security manager exists and its {@link 1343 * java.lang.SecurityManager#checkRead(java.lang.String)} 1344 * method does not permit verification of the existence of the 1345 * named directory and all necessary parent directories; or if 1346 * the {@link 1347 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1348 * method does not permit the named directory and all necessary 1349 * parent directories to be created 1350 */ 1351 public boolean mkdirs() { 1352 if (exists()) { 1353 return false; 1354 } 1355 if (mkdir()) { 1356 return true; 1357 } 1358 File canonFile = null; 1359 try { 1360 canonFile = getCanonicalFile(); 1361 } catch (IOException e) { 1362 return false; 1363 } 1364 1365 File parent = canonFile.getParentFile(); 1366 return (parent != null && (parent.mkdirs() || parent.exists()) && 1367 canonFile.mkdir()); 1368 } 1369 1370 /** 1371 * Renames the file denoted by this abstract pathname. 1372 * 1373 * <p> Many aspects of the behavior of this method are inherently 1374 * platform-dependent: The rename operation might not be able to move a 1375 * file from one filesystem to another, it might not be atomic, and it 1376 * might not succeed if a file with the destination abstract pathname 1377 * already exists. The return value should always be checked to make sure 1378 * that the rename operation was successful. 1379 * 1380 * <p> Note that the {@link java.nio.file.Files} class defines the {@link 1381 * java.nio.file.Files#move move} method to move or rename a file in a 1382 * platform independent manner. 1383 * 1384 * @param dest The new abstract pathname for the named file 1385 * 1386 * @return <code>true</code> if and only if the renaming succeeded; 1387 * <code>false</code> otherwise 1388 * 1389 * @throws SecurityException 1390 * If a security manager exists and its {@link 1391 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1392 * method denies write access to either the old or new pathnames 1393 * 1394 * @throws NullPointerException 1395 * If parameter <code>dest</code> is <code>null</code> 1396 */ 1397 public boolean renameTo(File dest) { 1398 if (dest == null) { 1399 throw new NullPointerException(); 1400 } 1401 SecurityManager security = System.getSecurityManager(); 1402 if (security != null) { 1403 security.checkWrite(path); 1404 security.checkWrite(dest.path); 1405 } 1406 if (this.isInvalid() || dest.isInvalid()) { 1407 return false; 1408 } 1409 return fs.rename(this, dest); 1410 } 1411 1412 /** 1413 * Sets the last-modified time of the file or directory named by this 1414 * abstract pathname. 1415 * 1416 * <p> All platforms support file-modification times to the nearest second, 1417 * but some provide more precision. The argument will be truncated to fit 1418 * the supported precision. If the operation succeeds and no intervening 1419 * operations on the file take place, then the next invocation of the 1420 * {@link #lastModified} method will return the (possibly 1421 * truncated) <code>time</code> argument that was passed to this method. 1422 * 1423 * @param time The new last-modified time, measured in milliseconds since 1424 * the epoch (00:00:00 GMT, January 1, 1970) 1425 * 1426 * @return <code>true</code> if and only if the operation succeeded; 1427 * <code>false</code> otherwise 1428 * 1429 * @throws IllegalArgumentException If the argument is negative 1430 * 1431 * @throws SecurityException 1432 * If a security manager exists and its {@link 1433 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1434 * method denies write access to the named file 1435 * 1436 * @since 1.2 1437 */ 1438 public boolean setLastModified(long time) { 1439 if (time < 0) throw new IllegalArgumentException("Negative time"); 1440 SecurityManager security = System.getSecurityManager(); 1441 if (security != null) { 1442 security.checkWrite(path); 1443 } 1444 if (isInvalid()) { 1445 return false; 1446 } 1447 return fs.setLastModifiedTime(this, time); 1448 } 1449 1450 /** 1451 * Marks the file or directory named by this abstract pathname so that 1452 * only read operations are allowed. After invoking this method the file 1453 * or directory will not change until it is either deleted or marked 1454 * to allow write access. On some platforms it may be possible to start the 1455 * Java virtual machine with special privileges that allow it to modify 1456 * files that are marked read-only. Whether or not a read-only file or 1457 * directory may be deleted depends upon the underlying system. 1458 * 1459 * @return <code>true</code> if and only if the operation succeeded; 1460 * <code>false</code> otherwise 1461 * 1462 * @throws SecurityException 1463 * If a security manager exists and its {@link 1464 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1465 * method denies write access to the named file 1466 * 1467 * @since 1.2 1468 */ 1469 public boolean setReadOnly() { 1470 SecurityManager security = System.getSecurityManager(); 1471 if (security != null) { 1472 security.checkWrite(path); 1473 } 1474 if (isInvalid()) { 1475 return false; 1476 } 1477 return fs.setReadOnly(this); 1478 } 1479 1480 /** 1481 * Sets the owner's or everybody's write permission for this abstract 1482 * pathname. On some platforms it may be possible to start the Java virtual 1483 * machine with special privileges that allow it to modify files that 1484 * disallow write operations. 1485 * 1486 * <p> The {@link java.nio.file.Files} class defines methods that operate on 1487 * file attributes including file permissions. This may be used when finer 1488 * manipulation of file permissions is required. 1489 * 1490 * @param writable 1491 * If <code>true</code>, sets the access permission to allow write 1492 * operations; if <code>false</code> to disallow write operations 1493 * 1494 * @param ownerOnly 1495 * If <code>true</code>, the write permission applies only to the 1496 * owner's write permission; otherwise, it applies to everybody. If 1497 * the underlying file system can not distinguish the owner's write 1498 * permission from that of others, then the permission will apply to 1499 * everybody, regardless of this value. 1500 * 1501 * @return <code>true</code> if and only if the operation succeeded. The 1502 * operation will fail if the user does not have permission to change 1503 * the access permissions of this abstract pathname. 1504 * 1505 * @throws SecurityException 1506 * If a security manager exists and its {@link 1507 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1508 * method denies write access to the named file 1509 * 1510 * @since 1.6 1511 */ 1512 public boolean setWritable(boolean writable, boolean ownerOnly) { 1513 SecurityManager security = System.getSecurityManager(); 1514 if (security != null) { 1515 security.checkWrite(path); 1516 } 1517 if (isInvalid()) { 1518 return false; 1519 } 1520 return fs.setPermission(this, FileSystem.ACCESS_WRITE, writable, ownerOnly); 1521 } 1522 1523 /** 1524 * A convenience method to set the owner's write permission for this abstract 1525 * pathname. On some platforms it may be possible to start the Java virtual 1526 * machine with special privileges that allow it to modify files that 1527 * disallow write operations. 1528 * 1529 * <p> An invocation of this method of the form {@code file.setWritable(arg)} 1530 * behaves in exactly the same way as the invocation 1531 * 1532 * <pre>{@code 1533 * file.setWritable(arg, true) 1534 * }</pre> 1535 * 1536 * @param writable 1537 * If <code>true</code>, sets the access permission to allow write 1538 * operations; if <code>false</code> to disallow write operations 1539 * 1540 * @return <code>true</code> if and only if the operation succeeded. The 1541 * operation will fail if the user does not have permission to 1542 * change the access permissions of this abstract pathname. 1543 * 1544 * @throws SecurityException 1545 * If a security manager exists and its {@link 1546 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1547 * method denies write access to the file 1548 * 1549 * @since 1.6 1550 */ 1551 public boolean setWritable(boolean writable) { 1552 return setWritable(writable, true); 1553 } 1554 1555 /** 1556 * Sets the owner's or everybody's read permission for this abstract 1557 * pathname. On some platforms it may be possible to start the Java virtual 1558 * machine with special privileges that allow it to read files that are 1559 * marked as unreadable. 1560 * 1561 * <p> The {@link java.nio.file.Files} class defines methods that operate on 1562 * file attributes including file permissions. This may be used when finer 1563 * manipulation of file permissions is required. 1564 * 1565 * @param readable 1566 * If <code>true</code>, sets the access permission to allow read 1567 * operations; if <code>false</code> to disallow read operations 1568 * 1569 * @param ownerOnly 1570 * If <code>true</code>, the read permission applies only to the 1571 * owner's read permission; otherwise, it applies to everybody. If 1572 * the underlying file system can not distinguish the owner's read 1573 * permission from that of others, then the permission will apply to 1574 * everybody, regardless of this value. 1575 * 1576 * @return <code>true</code> if and only if the operation succeeded. The 1577 * operation will fail if the user does not have permission to 1578 * change the access permissions of this abstract pathname. If 1579 * <code>readable</code> is <code>false</code> and the underlying 1580 * file system does not implement a read permission, then the 1581 * operation will fail. 1582 * 1583 * @throws SecurityException 1584 * If a security manager exists and its {@link 1585 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1586 * method denies write access to the file 1587 * 1588 * @since 1.6 1589 */ 1590 public boolean setReadable(boolean readable, boolean ownerOnly) { 1591 SecurityManager security = System.getSecurityManager(); 1592 if (security != null) { 1593 security.checkWrite(path); 1594 } 1595 if (isInvalid()) { 1596 return false; 1597 } 1598 return fs.setPermission(this, FileSystem.ACCESS_READ, readable, ownerOnly); 1599 } 1600 1601 /** 1602 * A convenience method to set the owner's read permission for this abstract 1603 * pathname. On some platforms it may be possible to start the Java virtual 1604 * machine with special privileges that allow it to read files that are 1605 * marked as unreadable. 1606 * 1607 * <p>An invocation of this method of the form {@code file.setReadable(arg)} 1608 * behaves in exactly the same way as the invocation 1609 * 1610 * <pre>{@code 1611 * file.setReadable(arg, true) 1612 * }</pre> 1613 * 1614 * @param readable 1615 * If <code>true</code>, sets the access permission to allow read 1616 * operations; if <code>false</code> to disallow read operations 1617 * 1618 * @return <code>true</code> if and only if the operation succeeded. The 1619 * operation will fail if the user does not have permission to 1620 * change the access permissions of this abstract pathname. If 1621 * <code>readable</code> is <code>false</code> and the underlying 1622 * file system does not implement a read permission, then the 1623 * operation will fail. 1624 * 1625 * @throws SecurityException 1626 * If a security manager exists and its {@link 1627 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1628 * method denies write access to the file 1629 * 1630 * @since 1.6 1631 */ 1632 public boolean setReadable(boolean readable) { 1633 return setReadable(readable, true); 1634 } 1635 1636 /** 1637 * Sets the owner's or everybody's execute permission for this abstract 1638 * pathname. On some platforms it may be possible to start the Java virtual 1639 * machine with special privileges that allow it to execute files that are 1640 * not marked executable. 1641 * 1642 * <p> The {@link java.nio.file.Files} class defines methods that operate on 1643 * file attributes including file permissions. This may be used when finer 1644 * manipulation of file permissions is required. 1645 * 1646 * @param executable 1647 * If <code>true</code>, sets the access permission to allow execute 1648 * operations; if <code>false</code> to disallow execute operations 1649 * 1650 * @param ownerOnly 1651 * If <code>true</code>, the execute permission applies only to the 1652 * owner's execute permission; otherwise, it applies to everybody. 1653 * If the underlying file system can not distinguish the owner's 1654 * execute permission from that of others, then the permission will 1655 * apply to everybody, regardless of this value. 1656 * 1657 * @return <code>true</code> if and only if the operation succeeded. The 1658 * operation will fail if the user does not have permission to 1659 * change the access permissions of this abstract pathname. If 1660 * <code>executable</code> is <code>false</code> and the underlying 1661 * file system does not implement an execute permission, then the 1662 * operation will fail. 1663 * 1664 * @throws SecurityException 1665 * If a security manager exists and its {@link 1666 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1667 * method denies write access to the file 1668 * 1669 * @since 1.6 1670 */ 1671 public boolean setExecutable(boolean executable, boolean ownerOnly) { 1672 SecurityManager security = System.getSecurityManager(); 1673 if (security != null) { 1674 security.checkWrite(path); 1675 } 1676 if (isInvalid()) { 1677 return false; 1678 } 1679 return fs.setPermission(this, FileSystem.ACCESS_EXECUTE, executable, ownerOnly); 1680 } 1681 1682 /** 1683 * A convenience method to set the owner's execute permission for this 1684 * abstract pathname. On some platforms it may be possible to start the Java 1685 * virtual machine with special privileges that allow it to execute files 1686 * that are not marked executable. 1687 * 1688 * <p>An invocation of this method of the form {@code file.setExcutable(arg)} 1689 * behaves in exactly the same way as the invocation 1690 * 1691 * <pre>{@code 1692 * file.setExecutable(arg, true) 1693 * }</pre> 1694 * 1695 * @param executable 1696 * If <code>true</code>, sets the access permission to allow execute 1697 * operations; if <code>false</code> to disallow execute operations 1698 * 1699 * @return <code>true</code> if and only if the operation succeeded. The 1700 * operation will fail if the user does not have permission to 1701 * change the access permissions of this abstract pathname. If 1702 * <code>executable</code> is <code>false</code> and the underlying 1703 * file system does not implement an execute permission, then the 1704 * operation will fail. 1705 * 1706 * @throws SecurityException 1707 * If a security manager exists and its {@link 1708 * java.lang.SecurityManager#checkWrite(java.lang.String)} 1709 * method denies write access to the file 1710 * 1711 * @since 1.6 1712 */ 1713 public boolean setExecutable(boolean executable) { 1714 return setExecutable(executable, true); 1715 } 1716 1717 /** 1718 * Tests whether the application can execute the file denoted by this 1719 * abstract pathname. On some platforms it may be possible to start the 1720 * Java virtual machine with special privileges that allow it to execute 1721 * files that are not marked executable. Consequently this method may return 1722 * {@code true} even though the file does not have execute permissions. 1723 * 1724 * @return <code>true</code> if and only if the abstract pathname exists 1725 * <em>and</em> the application is allowed to execute the file 1726 * 1727 * @throws SecurityException 1728 * If a security manager exists and its {@link 1729 * java.lang.SecurityManager#checkExec(java.lang.String)} 1730 * method denies execute access to the file 1731 * 1732 * @since 1.6 1733 */ 1734 public boolean canExecute() { 1735 SecurityManager security = System.getSecurityManager(); 1736 if (security != null) { 1737 security.checkExec(path); 1738 } 1739 if (isInvalid()) { 1740 return false; 1741 } 1742 return fs.checkAccess(this, FileSystem.ACCESS_EXECUTE); 1743 } 1744 1745 1746 /* -- Filesystem interface -- */ 1747 1748 /** 1749 * List the available filesystem roots. 1750 * 1751 * <p> A particular Java platform may support zero or more 1752 * hierarchically-organized file systems. Each file system has a 1753 * {@code root} directory from which all other files in that file system 1754 * can be reached. Windows platforms, for example, have a root directory 1755 * for each active drive; UNIX platforms have a single root directory, 1756 * namely {@code "/"}. The set of available filesystem roots is affected 1757 * by various system-level operations such as the insertion or ejection of 1758 * removable media and the disconnecting or unmounting of physical or 1759 * virtual disk drives. 1760 * 1761 * <p> This method returns an array of {@code File} objects that denote the 1762 * root directories of the available filesystem roots. It is guaranteed 1763 * that the canonical pathname of any file physically present on the local 1764 * machine will begin with one of the roots returned by this method. 1765 * 1766 * <p> The canonical pathname of a file that resides on some other machine 1767 * and is accessed via a remote-filesystem protocol such as SMB or NFS may 1768 * or may not begin with one of the roots returned by this method. If the 1769 * pathname of a remote file is syntactically indistinguishable from the 1770 * pathname of a local file then it will begin with one of the roots 1771 * returned by this method. Thus, for example, {@code File} objects 1772 * denoting the root directories of the mapped network drives of a Windows 1773 * platform will be returned by this method, while {@code File} objects 1774 * containing UNC pathnames will not be returned by this method. 1775 * 1776 * <p> Unlike most methods in this class, this method does not throw 1777 * security exceptions. If a security manager exists and its {@link 1778 * SecurityManager#checkRead(String)} method denies read access to a 1779 * particular root directory, then that directory will not appear in the 1780 * result. 1781 * 1782 * @return An array of {@code File} objects denoting the available 1783 * filesystem roots, or {@code null} if the set of roots could not 1784 * be determined. The array will be empty if there are no 1785 * filesystem roots. 1786 * 1787 * @since 1.2 1788 * @see java.nio.file.FileStore 1789 */ 1790 public static File[] listRoots() { 1791 return fs.listRoots(); 1792 } 1793 1794 1795 /* -- Disk usage -- */ 1796 1797 /** 1798 * Returns the size of the partition <a href="#partName">named</a> by this 1799 * abstract pathname. 1800 * 1801 * @return The size, in bytes, of the partition or {@code 0L} if this 1802 * abstract pathname does not name a partition 1803 * 1804 * @throws SecurityException 1805 * If a security manager has been installed and it denies 1806 * {@link RuntimePermission}{@code ("getFileSystemAttributes")} 1807 * or its {@link SecurityManager#checkRead(String)} method denies 1808 * read access to the file named by this abstract pathname 1809 * 1810 * @since 1.6 1811 */ 1812 public long getTotalSpace() { 1813 SecurityManager sm = System.getSecurityManager(); 1814 if (sm != null) { 1815 sm.checkPermission(new RuntimePermission("getFileSystemAttributes")); 1816 sm.checkRead(path); 1817 } 1818 if (isInvalid()) { 1819 return 0L; 1820 } 1821 return fs.getSpace(this, FileSystem.SPACE_TOTAL); 1822 } 1823 1824 /** 1825 * Returns the number of unallocated bytes in the partition <a 1826 * href="#partName">named</a> by this abstract path name. 1827 * 1828 * <p> The returned number of unallocated bytes is a hint, but not 1829 * a guarantee, that it is possible to use most or any of these 1830 * bytes. The number of unallocated bytes is most likely to be 1831 * accurate immediately after this call. It is likely to be made 1832 * inaccurate by any external I/O operations including those made 1833 * on the system outside of this virtual machine. This method 1834 * makes no guarantee that write operations to this file system 1835 * will succeed. 1836 * 1837 * @return The number of unallocated bytes on the partition or {@code 0L} 1838 * if the abstract pathname does not name a partition. This 1839 * value will be less than or equal to the total file system size 1840 * returned by {@link #getTotalSpace}. 1841 * 1842 * @throws SecurityException 1843 * If a security manager has been installed and it denies 1844 * {@link RuntimePermission}{@code ("getFileSystemAttributes")} 1845 * or its {@link SecurityManager#checkRead(String)} method denies 1846 * read access to the file named by this abstract pathname 1847 * 1848 * @since 1.6 1849 */ 1850 public long getFreeSpace() { 1851 SecurityManager sm = System.getSecurityManager(); 1852 if (sm != null) { 1853 sm.checkPermission(new RuntimePermission("getFileSystemAttributes")); 1854 sm.checkRead(path); 1855 } 1856 if (isInvalid()) { 1857 return 0L; 1858 } 1859 return fs.getSpace(this, FileSystem.SPACE_FREE); 1860 } 1861 1862 /** 1863 * Returns the number of bytes available to this virtual machine on the 1864 * partition <a href="#partName">named</a> by this abstract pathname. When 1865 * possible, this method checks for write permissions and other operating 1866 * system restrictions and will therefore usually provide a more accurate 1867 * estimate of how much new data can actually be written than {@link 1868 * #getFreeSpace}. 1869 * 1870 * <p> The returned number of available bytes is a hint, but not a 1871 * guarantee, that it is possible to use most or any of these bytes. The 1872 * number of available bytes is most likely to be accurate immediately 1873 * after this call. It is likely to be made inaccurate by any external 1874 * I/O operations including those made on the system outside of this 1875 * virtual machine. This method makes no guarantee that write operations 1876 * to this file system will succeed. 1877 * 1878 * @return The number of available bytes on the partition or {@code 0L} 1879 * if the abstract pathname does not name a partition. On 1880 * systems where this information is not available, this method 1881 * will be equivalent to a call to {@link #getFreeSpace}. 1882 * 1883 * @throws SecurityException 1884 * If a security manager has been installed and it denies 1885 * {@link RuntimePermission}{@code ("getFileSystemAttributes")} 1886 * or its {@link SecurityManager#checkRead(String)} method denies 1887 * read access to the file named by this abstract pathname 1888 * 1889 * @since 1.6 1890 */ 1891 public long getUsableSpace() { 1892 SecurityManager sm = System.getSecurityManager(); 1893 if (sm != null) { 1894 sm.checkPermission(new RuntimePermission("getFileSystemAttributes")); 1895 sm.checkRead(path); 1896 } 1897 if (isInvalid()) { 1898 return 0L; 1899 } 1900 return fs.getSpace(this, FileSystem.SPACE_USABLE); 1901 } 1902 1903 /* -- Temporary files -- */ 1904 1905 private static class TempDirectory { 1906 private TempDirectory() { } 1907 1908 // temporary directory location 1909 private static final File tmpdir = new File( 1910 GetPropertyAction.privilegedGetProperty("java.io.tmpdir")); 1911 static File location() { 1912 return tmpdir; 1913 } 1914 1915 // file name generation 1916 private static final SecureRandom random = new SecureRandom(); 1917 private static int shortenSubName(int subNameLength, int excess, 1918 int nameMin) { 1919 int newLength = Math.max(nameMin, subNameLength - excess); 1920 if (newLength < subNameLength) { 1921 return newLength; 1922 } 1923 return subNameLength; 1924 } 1925 static File generateFile(String prefix, String suffix, File dir) 1926 throws IOException 1927 { 1928 long n = random.nextLong(); 1929 String nus = Long.toUnsignedString(n); 1930 1931 // Use only the file name from the supplied prefix 1932 prefix = (new File(prefix)).getName(); 1933 1934 int prefixLength = prefix.length(); 1935 int nusLength = nus.length(); 1936 int suffixLength = suffix.length();; 1937 1938 String name; 1939 int nameMax = fs.getNameMax(dir.getPath()); 1940 int excess = prefixLength + nusLength + suffixLength - nameMax; 1941 if (excess <= 0) { 1942 name = prefix + nus + suffix; 1943 } else { 1944 // Name exceeds the maximum path component length: shorten it 1945 1946 // Attempt to shorten the prefix length to no less then 3 1947 prefixLength = shortenSubName(prefixLength, excess, 3); 1948 excess = prefixLength + nusLength + suffixLength - nameMax; 1949 1950 if (excess > 0) { 1951 // Attempt to shorten the suffix length to no less than 1952 // 0 or 4 depending on whether it begins with a dot ('.') 1953 suffixLength = shortenSubName(suffixLength, excess, 1954 suffix.indexOf(".") == 0 ? 4 : 0); 1955 suffixLength = shortenSubName(suffixLength, excess, 3); 1956 excess = prefixLength + nusLength + suffixLength - nameMax; 1957 } 1958 1959 if (excess > 0 && excess <= nusLength - 5) { 1960 // Attempt to shorten the random character string length 1961 // to no less than 5 1962 nusLength = shortenSubName(nusLength, excess, 5); 1963 } 1964 1965 StringBuilder sb = 1966 new StringBuilder(prefixLength + nusLength + suffixLength); 1967 sb.append(prefixLength < prefix.length() ? 1968 prefix.substring(0, prefixLength) : prefix); 1969 sb.append(nusLength < nus.length() ? 1970 nus.substring(0, nusLength) : nus); 1971 sb.append(suffixLength < suffix.length() ? 1972 suffix.substring(0, suffixLength) : suffix); 1973 name = sb.toString(); 1974 } 1975 1976 // Normalize the path component 1977 name = fs.normalize(name); 1978 1979 File f = new File(dir, name); 1980 if (!name.equals(f.getName()) || f.isInvalid()) { 1981 if (System.getSecurityManager() != null) 1982 throw new IOException("Unable to create temporary file"); 1983 else 1984 throw new IOException("Unable to create temporary file, " 1985 + name); 1986 } 1987 return f; 1988 } 1989 } 1990 1991 /** 1992 * <p> Creates a new empty file in the specified directory, using the 1993 * given prefix and suffix strings to generate its name. If this method 1994 * returns successfully then it is guaranteed that: 1995 * 1996 * <ol> 1997 * <li> The file denoted by the returned abstract pathname did not exist 1998 * before this method was invoked, and 1999 * <li> Neither this method nor any of its variants will return the same 2000 * abstract pathname again in the current invocation of the virtual 2001 * machine. 2002 * </ol> 2003 * 2004 * This method provides only part of a temporary-file facility. To arrange 2005 * for a file created by this method to be deleted automatically, use the 2006 * {@link #deleteOnExit} method. 2007 * 2008 * <p> The <code>prefix</code> argument must be at least three characters 2009 * long. It is recommended that the prefix be a short, meaningful string 2010 * such as <code>"hjb"</code> or <code>"mail"</code>. The 2011 * <code>suffix</code> argument may be <code>null</code>, in which case the 2012 * suffix <code>".tmp"</code> will be used. 2013 * 2014 * <p> To create the new file, the prefix and the suffix may first be 2015 * adjusted to fit the limitations of the underlying platform. If the 2016 * prefix is too long then it will be truncated, but its first three 2017 * characters will always be preserved. If the suffix is too long then it 2018 * too will be truncated, but if it begins with a period character 2019 * (<code>'.'</code>) then the period and the first three characters 2020 * following it will always be preserved. Once these adjustments have been 2021 * made the name of the new file will be generated by concatenating the 2022 * prefix, five or more internally-generated characters, and the suffix. 2023 * 2024 * <p> If the <code>directory</code> argument is <code>null</code> then the 2025 * system-dependent default temporary-file directory will be used. The 2026 * default temporary-file directory is specified by the system property 2027 * <code>java.io.tmpdir</code>. On UNIX systems the default value of this 2028 * property is typically <code>"/tmp"</code> or <code>"/var/tmp"</code>; on 2029 * Microsoft Windows systems it is typically <code>"C:\\WINNT\\TEMP"</code>. A different 2030 * value may be given to this system property when the Java virtual machine 2031 * is invoked, but programmatic changes to this property are not guaranteed 2032 * to have any effect upon the temporary directory used by this method. 2033 * 2034 * @param prefix The prefix string to be used in generating the file's 2035 * name; must be at least three characters long 2036 * 2037 * @param suffix The suffix string to be used in generating the file's 2038 * name; may be <code>null</code>, in which case the 2039 * suffix <code>".tmp"</code> will be used 2040 * 2041 * @param directory The directory in which the file is to be created, or 2042 * <code>null</code> if the default temporary-file 2043 * directory is to be used 2044 * 2045 * @return An abstract pathname denoting a newly-created empty file 2046 * 2047 * @throws IllegalArgumentException 2048 * If the <code>prefix</code> argument contains fewer than three 2049 * characters 2050 * 2051 * @throws IOException If a file could not be created 2052 * 2053 * @throws SecurityException 2054 * If a security manager exists and its {@link 2055 * java.lang.SecurityManager#checkWrite(java.lang.String)} 2056 * method does not allow a file to be created 2057 * 2058 * @since 1.2 2059 */ 2060 public static File createTempFile(String prefix, String suffix, 2061 File directory) 2062 throws IOException 2063 { 2064 if (prefix.length() < 3) { 2065 throw new IllegalArgumentException("Prefix string \"" + prefix + 2066 "\" too short: length must be at least 3"); 2067 } 2068 if (suffix == null) 2069 suffix = ".tmp"; 2070 2071 File tmpdir = (directory != null) ? directory 2072 : TempDirectory.location(); 2073 SecurityManager sm = System.getSecurityManager(); 2074 File f; 2075 do { 2076 f = TempDirectory.generateFile(prefix, suffix, tmpdir); 2077 2078 if (sm != null) { 2079 try { 2080 sm.checkWrite(f.getPath()); 2081 } catch (SecurityException se) { 2082 // don't reveal temporary directory location 2083 if (directory == null) 2084 throw new SecurityException("Unable to create temporary file"); 2085 throw se; 2086 } 2087 } 2088 } while ((fs.getBooleanAttributes(f) & FileSystem.BA_EXISTS) != 0); 2089 2090 if (!fs.createFileExclusively(f.getPath())) 2091 throw new IOException("Unable to create temporary file"); 2092 2093 return f; 2094 } 2095 2096 /** 2097 * Creates an empty file in the default temporary-file directory, using 2098 * the given prefix and suffix to generate its name. Invoking this method 2099 * is equivalent to invoking {@link #createTempFile(java.lang.String, 2100 * java.lang.String, java.io.File) 2101 * createTempFile(prefix, suffix, null)}. 2102 * 2103 * <p> The {@link 2104 * java.nio.file.Files#createTempFile(String,String,java.nio.file.attribute.FileAttribute[]) 2105 * Files.createTempFile} method provides an alternative method to create an 2106 * empty file in the temporary-file directory. Files created by that method 2107 * may have more restrictive access permissions to files created by this 2108 * method and so may be more suited to security-sensitive applications. 2109 * 2110 * @param prefix The prefix string to be used in generating the file's 2111 * name; must be at least three characters long 2112 * 2113 * @param suffix The suffix string to be used in generating the file's 2114 * name; may be <code>null</code>, in which case the 2115 * suffix <code>".tmp"</code> will be used 2116 * 2117 * @return An abstract pathname denoting a newly-created empty file 2118 * 2119 * @throws IllegalArgumentException 2120 * If the <code>prefix</code> argument contains fewer than three 2121 * characters 2122 * 2123 * @throws IOException If a file could not be created 2124 * 2125 * @throws SecurityException 2126 * If a security manager exists and its {@link 2127 * java.lang.SecurityManager#checkWrite(java.lang.String)} 2128 * method does not allow a file to be created 2129 * 2130 * @since 1.2 2131 * @see java.nio.file.Files#createTempDirectory(String,FileAttribute[]) 2132 */ 2133 public static File createTempFile(String prefix, String suffix) 2134 throws IOException 2135 { 2136 return createTempFile(prefix, suffix, null); 2137 } 2138 2139 /* -- Basic infrastructure -- */ 2140 2141 /** 2142 * Compares two abstract pathnames lexicographically. The ordering 2143 * defined by this method depends upon the underlying system. On UNIX 2144 * systems, alphabetic case is significant in comparing pathnames; on Microsoft Windows 2145 * systems it is not. 2146 * 2147 * @param pathname The abstract pathname to be compared to this abstract 2148 * pathname 2149 * 2150 * @return Zero if the argument is equal to this abstract pathname, a 2151 * value less than zero if this abstract pathname is 2152 * lexicographically less than the argument, or a value greater 2153 * than zero if this abstract pathname is lexicographically 2154 * greater than the argument 2155 * 2156 * @since 1.2 2157 */ 2158 public int compareTo(File pathname) { 2159 return fs.compare(this, pathname); 2160 } 2161 2162 /** 2163 * Tests this abstract pathname for equality with the given object. 2164 * Returns <code>true</code> if and only if the argument is not 2165 * <code>null</code> and is an abstract pathname that denotes the same file 2166 * or directory as this abstract pathname. Whether or not two abstract 2167 * pathnames are equal depends upon the underlying system. On UNIX 2168 * systems, alphabetic case is significant in comparing pathnames; on Microsoft Windows 2169 * systems it is not. 2170 * 2171 * @param obj The object to be compared with this abstract pathname 2172 * 2173 * @return <code>true</code> if and only if the objects are the same; 2174 * <code>false</code> otherwise 2175 */ 2176 public boolean equals(Object obj) { 2177 if ((obj != null) && (obj instanceof File)) { 2178 return compareTo((File)obj) == 0; 2179 } 2180 return false; 2181 } 2182 2183 /** 2184 * Computes a hash code for this abstract pathname. Because equality of 2185 * abstract pathnames is inherently system-dependent, so is the computation 2186 * of their hash codes. On UNIX systems, the hash code of an abstract 2187 * pathname is equal to the exclusive <em>or</em> of the hash code 2188 * of its pathname string and the decimal value 2189 * <code>1234321</code>. On Microsoft Windows systems, the hash 2190 * code is equal to the exclusive <em>or</em> of the hash code of 2191 * its pathname string converted to lower case and the decimal 2192 * value <code>1234321</code>. Locale is not taken into account on 2193 * lowercasing the pathname string. 2194 * 2195 * @return A hash code for this abstract pathname 2196 */ 2197 public int hashCode() { 2198 return fs.hashCode(this); 2199 } 2200 2201 /** 2202 * Returns the pathname string of this abstract pathname. This is just the 2203 * string returned by the {@link #getPath} method. 2204 * 2205 * @return The string form of this abstract pathname 2206 */ 2207 public String toString() { 2208 return getPath(); 2209 } 2210 2211 /** 2212 * WriteObject is called to save this filename. 2213 * The separator character is saved also so it can be replaced 2214 * in case the path is reconstituted on a different host type. 2215 * 2216 * @serialData Default fields followed by separator character. 2217 */ 2218 private synchronized void writeObject(java.io.ObjectOutputStream s) 2219 throws IOException 2220 { 2221 s.defaultWriteObject(); 2222 s.writeChar(separatorChar); // Add the separator character 2223 } 2224 2225 /** 2226 * readObject is called to restore this filename. 2227 * The original separator character is read. If it is different 2228 * than the separator character on this system, then the old separator 2229 * is replaced by the local separator. 2230 */ 2231 private synchronized void readObject(java.io.ObjectInputStream s) 2232 throws IOException, ClassNotFoundException 2233 { 2234 ObjectInputStream.GetField fields = s.readFields(); 2235 String pathField = (String)fields.get("path", null); 2236 char sep = s.readChar(); // read the previous separator char 2237 if (sep != separatorChar) 2238 pathField = pathField.replace(sep, separatorChar); 2239 String path = fs.normalize(pathField); 2240 UNSAFE.putReference(this, PATH_OFFSET, path); 2241 UNSAFE.putIntVolatile(this, PREFIX_LENGTH_OFFSET, fs.prefixLength(path)); 2242 } 2243 2244 private static final jdk.internal.misc.Unsafe UNSAFE 2245 = jdk.internal.misc.Unsafe.getUnsafe(); 2246 private static final long PATH_OFFSET 2247 = UNSAFE.objectFieldOffset(File.class, "path"); 2248 private static final long PREFIX_LENGTH_OFFSET 2249 = UNSAFE.objectFieldOffset(File.class, "prefixLength"); 2250 2251 /** use serialVersionUID from JDK 1.0.2 for interoperability */ 2252 private static final long serialVersionUID = 301077366599181567L; 2253 2254 // -- Integration with java.nio.file -- 2255 2256 private transient volatile Path filePath; 2257 2258 /** 2259 * Returns a {@link Path java.nio.file.Path} object constructed from 2260 * this abstract path. The resulting {@code Path} is associated with the 2261 * {@link java.nio.file.FileSystems#getDefault default-filesystem}. 2262 * 2263 * <p> The first invocation of this method works as if invoking it were 2264 * equivalent to evaluating the expression: 2265 * <blockquote><pre> 2266 * {@link java.nio.file.FileSystems#getDefault FileSystems.getDefault}().{@link 2267 * java.nio.file.FileSystem#getPath getPath}(this.{@link #getPath getPath}()); 2268 * </pre></blockquote> 2269 * Subsequent invocations of this method return the same {@code Path}. 2270 * 2271 * <p> If this abstract pathname is the empty abstract pathname then this 2272 * method returns a {@code Path} that may be used to access the current 2273 * user directory. 2274 * 2275 * @return a {@code Path} constructed from this abstract path 2276 * 2277 * @throws java.nio.file.InvalidPathException 2278 * if a {@code Path} object cannot be constructed from the abstract 2279 * path (see {@link java.nio.file.FileSystem#getPath FileSystem.getPath}) 2280 * 2281 * @since 1.7 2282 * @see Path#toFile 2283 */ 2284 public Path toPath() { 2285 Path result = filePath; 2286 if (result == null) { 2287 synchronized (this) { 2288 result = filePath; 2289 if (result == null) { 2290 result = FileSystems.getDefault().getPath(path); 2291 filePath = result; 2292 } 2293 } 2294 } 2295 return result; 2296 } 2297 }