Mercurial > hg > icedtea9-forest > jdk
view src/solaris/classes/sun/nio/fs/UnixPath.java @ 5838:84cd98a5641c
7130915: File.equals does not give expected results when path contains Non-English characters on Mac OS X
Summary: to support Unicode nfd/nfc file path on Macos
Reviewed-by: alanb
| author | sherman |
|---|---|
| date | Thu, 19 Jul 2012 21:23:53 -0700 |
| parents | 516e0c884af2 |
| children |
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/* * Copyright (c) 2008, 2012, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ package sun.nio.fs; import java.nio.*; import java.nio.file.*; import java.nio.charset.*; import java.io.*; import java.net.URI; import java.util.*; import java.lang.ref.SoftReference; import static sun.nio.fs.UnixNativeDispatcher.*; import static sun.nio.fs.UnixConstants.*; /** * Solaris/Linux implementation of java.nio.file.Path */ class UnixPath extends AbstractPath { private static ThreadLocal<SoftReference<CharsetEncoder>> encoder = new ThreadLocal<SoftReference<CharsetEncoder>>(); // FIXME - eliminate this reference to reduce space private final UnixFileSystem fs; // internal representation private final byte[] path; // String representation (created lazily) private volatile String stringValue; // cached hashcode (created lazily, no need to be volatile) private int hash; // array of offsets of elements in path (created lazily) private volatile int[] offsets; UnixPath(UnixFileSystem fs, byte[] path) { this.fs = fs; this.path = path; } UnixPath(UnixFileSystem fs, String input) { // removes redundant slashes and checks for invalid characters this(fs, encode(fs, normalizeAndCheck(input))); } // package-private // removes redundant slashes and check input for invalid characters static String normalizeAndCheck(String input) { int n = input.length(); char prevChar = 0; for (int i=0; i < n; i++) { char c = input.charAt(i); if ((c == '/') && (prevChar == '/')) return normalize(input, n, i - 1); checkNotNul(input, c); prevChar = c; } if (prevChar == '/') return normalize(input, n, n - 1); return input; } private static void checkNotNul(String input, char c) { if (c == '\u0000') throw new InvalidPathException(input, "Nul character not allowed"); } private static String normalize(String input, int len, int off) { if (len == 0) return input; int n = len; while ((n > 0) && (input.charAt(n - 1) == '/')) n--; if (n == 0) return "/"; StringBuilder sb = new StringBuilder(input.length()); if (off > 0) sb.append(input.substring(0, off)); char prevChar = 0; for (int i=off; i < n; i++) { char c = input.charAt(i); if ((c == '/') && (prevChar == '/')) continue; checkNotNul(input, c); sb.append(c); prevChar = c; } return sb.toString(); } // encodes the given path-string into a sequence of bytes private static byte[] encode(UnixFileSystem fs, String input) { SoftReference<CharsetEncoder> ref = encoder.get(); CharsetEncoder ce = (ref != null) ? ref.get() : null; if (ce == null) { ce = Charset.defaultCharset().newEncoder() .onMalformedInput(CodingErrorAction.REPORT) .onUnmappableCharacter(CodingErrorAction.REPORT); encoder.set(new SoftReference<CharsetEncoder>(ce)); } char[] ca = fs.normalizeNativePath(input.toCharArray()); // size output buffer for worse-case size byte[] ba = new byte[(int)(ca.length * (double)ce.maxBytesPerChar())]; // encode ByteBuffer bb = ByteBuffer.wrap(ba); CharBuffer cb = CharBuffer.wrap(ca); ce.reset(); CoderResult cr = ce.encode(cb, bb, true); boolean error; if (!cr.isUnderflow()) { error = true; } else { cr = ce.flush(bb); error = !cr.isUnderflow(); } if (error) { throw new InvalidPathException(input, "Malformed input or input contains unmappable chacraters"); } // trim result to actual length if required int len = bb.position(); if (len != ba.length) ba = Arrays.copyOf(ba, len); return ba; } // package-private byte[] asByteArray() { return path; } // use this path when making system/library calls byte[] getByteArrayForSysCalls() { // resolve against default directory if required (chdir allowed or // file system default directory is not working directory) if (getFileSystem().needToResolveAgainstDefaultDirectory()) { return resolve(getFileSystem().defaultDirectory(), path); } else { if (!isEmpty()) { return path; } else { // empty path case will access current directory byte[] here = { '.' }; return here; } } } // use this message when throwing exceptions String getPathForExceptionMessage() { return toString(); } // use this path for permission checks String getPathForPermissionCheck() { if (getFileSystem().needToResolveAgainstDefaultDirectory()) { return new String(getByteArrayForSysCalls()); } else { return toString(); } } // Checks that the given file is a UnixPath static UnixPath toUnixPath(Path obj) { if (obj == null) throw new NullPointerException(); if (!(obj instanceof UnixPath)) throw new ProviderMismatchException(); return (UnixPath)obj; } // create offset list if not already created private void initOffsets() { if (offsets == null) { int count, index; // count names count = 0; index = 0; if (isEmpty()) { // empty path has one name count = 1; } else { while (index < path.length) { byte c = path[index++]; if (c != '/') { count++; while (index < path.length && path[index] != '/') index++; } } } // populate offsets int[] result = new int[count]; count = 0; index = 0; while (index < path.length) { byte c = path[index]; if (c == '/') { index++; } else { result[count++] = index++; while (index < path.length && path[index] != '/') index++; } } synchronized (this) { if (offsets == null) offsets = result; } } } // returns {@code true} if this path is an empty path private boolean isEmpty() { return path.length == 0; } // returns an empty path private UnixPath emptyPath() { return new UnixPath(getFileSystem(), new byte[0]); } @Override public UnixFileSystem getFileSystem() { return fs; } @Override public UnixPath getRoot() { if (path.length > 0 && path[0] == '/') { return getFileSystem().rootDirectory(); } else { return null; } } @Override public UnixPath getFileName() { initOffsets(); int count = offsets.length; // no elements so no name if (count == 0) return null; // one name element and no root component if (count == 1 && path.length > 0 && path[0] != '/') return this; int lastOffset = offsets[count-1]; int len = path.length - lastOffset; byte[] result = new byte[len]; System.arraycopy(path, lastOffset, result, 0, len); return new UnixPath(getFileSystem(), result); } @Override public UnixPath getParent() { initOffsets(); int count = offsets.length; if (count == 0) { // no elements so no parent return null; } int len = offsets[count-1] - 1; if (len <= 0) { // parent is root only (may be null) return getRoot(); } byte[] result = new byte[len]; System.arraycopy(path, 0, result, 0, len); return new UnixPath(getFileSystem(), result); } @Override public int getNameCount() { initOffsets(); return offsets.length; } @Override public UnixPath getName(int index) { initOffsets(); if (index < 0) throw new IllegalArgumentException(); if (index >= offsets.length) throw new IllegalArgumentException(); int begin = offsets[index]; int len; if (index == (offsets.length-1)) { len = path.length - begin; } else { len = offsets[index+1] - begin - 1; } // construct result byte[] result = new byte[len]; System.arraycopy(path, begin, result, 0, len); return new UnixPath(getFileSystem(), result); } @Override public UnixPath subpath(int beginIndex, int endIndex) { initOffsets(); if (beginIndex < 0) throw new IllegalArgumentException(); if (beginIndex >= offsets.length) throw new IllegalArgumentException(); if (endIndex > offsets.length) throw new IllegalArgumentException(); if (beginIndex >= endIndex) { throw new IllegalArgumentException(); } // starting offset and length int begin = offsets[beginIndex]; int len; if (endIndex == offsets.length) { len = path.length - begin; } else { len = offsets[endIndex] - begin - 1; } // construct result byte[] result = new byte[len]; System.arraycopy(path, begin, result, 0, len); return new UnixPath(getFileSystem(), result); } @Override public boolean isAbsolute() { return (path.length > 0 && path[0] == '/'); } // Resolve child against given base private static byte[] resolve(byte[] base, byte[] child) { int baseLength = base.length; int childLength = child.length; if (childLength == 0) return base; if (baseLength == 0 || child[0] == '/') return child; byte[] result; if (baseLength == 1 && base[0] == '/') { result = new byte[childLength + 1]; result[0] = '/'; System.arraycopy(child, 0, result, 1, childLength); } else { result = new byte[baseLength + 1 + childLength]; System.arraycopy(base, 0, result, 0, baseLength); result[base.length] = '/'; System.arraycopy(child, 0, result, baseLength+1, childLength); } return result; } @Override public UnixPath resolve(Path obj) { byte[] other = toUnixPath(obj).path; if (other.length > 0 && other[0] == '/') return ((UnixPath)obj); byte[] result = resolve(path, other); return new UnixPath(getFileSystem(), result); } UnixPath resolve(byte[] other) { return resolve(new UnixPath(getFileSystem(), other)); } @Override public UnixPath relativize(Path obj) { UnixPath other = toUnixPath(obj); if (other.equals(this)) return emptyPath(); // can only relativize paths of the same type if (this.isAbsolute() != other.isAbsolute()) throw new IllegalArgumentException("'other' is different type of Path"); // this path is the empty path if (this.isEmpty()) return other; int bn = this.getNameCount(); int cn = other.getNameCount(); // skip matching names int n = (bn > cn) ? cn : bn; int i = 0; while (i < n) { if (!this.getName(i).equals(other.getName(i))) break; i++; } int dotdots = bn - i; if (i < cn) { // remaining name components in other UnixPath remainder = other.subpath(i, cn); if (dotdots == 0) return remainder; // other is the empty path boolean isOtherEmpty = other.isEmpty(); // result is a "../" for each remaining name in base // followed by the remaining names in other. If the remainder is // the empty path then we don't add the final trailing slash. int len = dotdots*3 + remainder.path.length; if (isOtherEmpty) { assert remainder.isEmpty(); len--; } byte[] result = new byte[len]; int pos = 0; while (dotdots > 0) { result[pos++] = (byte)'.'; result[pos++] = (byte)'.'; if (isOtherEmpty) { if (dotdots > 1) result[pos++] = (byte)'/'; } else { result[pos++] = (byte)'/'; } dotdots--; } System.arraycopy(remainder.path, 0, result, pos, remainder.path.length); return new UnixPath(getFileSystem(), result); } else { // no remaining names in other so result is simply a sequence of ".." byte[] result = new byte[dotdots*3 - 1]; int pos = 0; while (dotdots > 0) { result[pos++] = (byte)'.'; result[pos++] = (byte)'.'; // no tailing slash at the end if (dotdots > 1) result[pos++] = (byte)'/'; dotdots--; } return new UnixPath(getFileSystem(), result); } } @Override public Path normalize() { final int count = getNameCount(); if (count == 0) return this; boolean[] ignore = new boolean[count]; // true => ignore name int[] size = new int[count]; // length of name int remaining = count; // number of names remaining boolean hasDotDot = false; // has at least one .. boolean isAbsolute = isAbsolute(); // first pass: // 1. compute length of names // 2. mark all occurences of "." to ignore // 3. and look for any occurences of ".." for (int i=0; i<count; i++) { int begin = offsets[i]; int len; if (i == (offsets.length-1)) { len = path.length - begin; } else { len = offsets[i+1] - begin - 1; } size[i] = len; if (path[begin] == '.') { if (len == 1) { ignore[i] = true; // ignore "." remaining--; } else { if (path[begin+1] == '.') // ".." found hasDotDot = true; } } } // multiple passes to eliminate all occurences of name/.. if (hasDotDot) { int prevRemaining; do { prevRemaining = remaining; int prevName = -1; for (int i=0; i<count; i++) { if (ignore[i]) continue; // not a ".." if (size[i] != 2) { prevName = i; continue; } int begin = offsets[i]; if (path[begin] != '.' || path[begin+1] != '.') { prevName = i; continue; } // ".." found if (prevName >= 0) { // name/<ignored>/.. found so mark name and ".." to be // ignored ignore[prevName] = true; ignore[i] = true; remaining = remaining - 2; prevName = -1; } else { // Case: /<ignored>/.. so mark ".." as ignored if (isAbsolute) { boolean hasPrevious = false; for (int j=0; j<i; j++) { if (!ignore[j]) { hasPrevious = true; break; } } if (!hasPrevious) { // all proceeding names are ignored ignore[i] = true; remaining--; } } } } } while (prevRemaining > remaining); } // no redundant names if (remaining == count) return this; // corner case - all names removed if (remaining == 0) { return isAbsolute ? getFileSystem().rootDirectory() : emptyPath(); } // compute length of result int len = remaining - 1; if (isAbsolute) len++; for (int i=0; i<count; i++) { if (!ignore[i]) len += size[i]; } byte[] result = new byte[len]; // copy names into result int pos = 0; if (isAbsolute) result[pos++] = '/'; for (int i=0; i<count; i++) { if (!ignore[i]) { System.arraycopy(path, offsets[i], result, pos, size[i]); pos += size[i]; if (--remaining > 0) { result[pos++] = '/'; } } } return new UnixPath(getFileSystem(), result); } @Override public boolean startsWith(Path other) { if (!(Objects.requireNonNull(other) instanceof UnixPath)) return false; UnixPath that = (UnixPath)other; // other path is longer if (that.path.length > path.length) return false; int thisOffsetCount = getNameCount(); int thatOffsetCount = that.getNameCount(); // other path has no name elements if (thatOffsetCount == 0 && this.isAbsolute()) { return that.isEmpty() ? false : true; } // given path has more elements that this path if (thatOffsetCount > thisOffsetCount) return false; // same number of elements so must be exact match if ((thatOffsetCount == thisOffsetCount) && (path.length != that.path.length)) { return false; } // check offsets of elements match for (int i=0; i<thatOffsetCount; i++) { Integer o1 = offsets[i]; Integer o2 = that.offsets[i]; if (!o1.equals(o2)) return false; } // offsets match so need to compare bytes int i=0; while (i < that.path.length) { if (this.path[i] != that.path[i]) return false; i++; } // final check that match is on name boundary if (i < path.length && this.path[i] != '/') return false; return true; } @Override public boolean endsWith(Path other) { if (!(Objects.requireNonNull(other) instanceof UnixPath)) return false; UnixPath that = (UnixPath)other; int thisLen = path.length; int thatLen = that.path.length; // other path is longer if (thatLen > thisLen) return false; // other path is the empty path if (thisLen > 0 && thatLen == 0) return false; // other path is absolute so this path must be absolute if (that.isAbsolute() && !this.isAbsolute()) return false; int thisOffsetCount = getNameCount(); int thatOffsetCount = that.getNameCount(); // given path has more elements that this path if (thatOffsetCount > thisOffsetCount) { return false; } else { // same number of elements if (thatOffsetCount == thisOffsetCount) { if (thisOffsetCount == 0) return true; int expectedLen = thisLen; if (this.isAbsolute() && !that.isAbsolute()) expectedLen--; if (thatLen != expectedLen) return false; } else { // this path has more elements so given path must be relative if (that.isAbsolute()) return false; } } // compare bytes int thisPos = offsets[thisOffsetCount - thatOffsetCount]; int thatPos = that.offsets[0]; if ((thatLen - thatPos) != (thisLen - thisPos)) return false; while (thatPos < thatLen) { if (this.path[thisPos++] != that.path[thatPos++]) return false; } return true; } @Override public int compareTo(Path other) { int len1 = path.length; int len2 = ((UnixPath) other).path.length; int n = Math.min(len1, len2); byte v1[] = path; byte v2[] = ((UnixPath) other).path; int k = 0; while (k < n) { int c1 = v1[k] & 0xff; int c2 = v2[k] & 0xff; if (c1 != c2) { return c1 - c2; } k++; } return len1 - len2; } @Override public boolean equals(Object ob) { if ((ob != null) && (ob instanceof UnixPath)) { return compareTo((Path)ob) == 0; } return false; } @Override public int hashCode() { // OK if two or more threads compute hash int h = hash; if (h == 0) { for (int i = 0; i< path.length; i++) { h = 31*h + (path[i] & 0xff); } hash = h; } return h; } @Override public String toString() { // OK if two or more threads create a String if (stringValue == null) { stringValue = fs.normalizeJavaPath(new String(path)); // platform encoding } return stringValue; } // -- file operations -- // package-private int openForAttributeAccess(boolean followLinks) throws IOException { int flags = O_RDONLY; if (!followLinks) { if (!supportsNoFollowLinks()) throw new IOException("NOFOLLOW_LINKS is not supported on this platform"); flags |= O_NOFOLLOW; } try { return open(this, flags, 0); } catch (UnixException x) { // HACK: EINVAL instead of ELOOP on Solaris 10 prior to u4 (see 6460380) if (getFileSystem().isSolaris() && x.errno() == EINVAL) x.setError(ELOOP); if (x.errno() == ELOOP) throw new FileSystemException(getPathForExceptionMessage(), null, x.getMessage() + " or unable to access attributes of symbolic link"); x.rethrowAsIOException(this); return -1; // keep compile happy } } void checkRead() { SecurityManager sm = System.getSecurityManager(); if (sm != null) sm.checkRead(getPathForPermissionCheck()); } void checkWrite() { SecurityManager sm = System.getSecurityManager(); if (sm != null) sm.checkWrite(getPathForPermissionCheck()); } void checkDelete() { SecurityManager sm = System.getSecurityManager(); if (sm != null) sm.checkDelete(getPathForPermissionCheck()); } @Override public UnixPath toAbsolutePath() { if (isAbsolute()) { return this; } // The path is relative so need to resolve against default directory, // taking care not to reveal the user.dir SecurityManager sm = System.getSecurityManager(); if (sm != null) { sm.checkPropertyAccess("user.dir"); } return new UnixPath(getFileSystem(), resolve(getFileSystem().defaultDirectory(), path)); } @Override public Path toRealPath(LinkOption... options) throws IOException { checkRead(); UnixPath absolute = toAbsolutePath(); // if resolving links then use realpath if (Util.followLinks(options)) { try { byte[] rp = realpath(absolute); return new UnixPath(getFileSystem(), rp); } catch (UnixException x) { x.rethrowAsIOException(this); } } // if not resolving links then eliminate "." and also ".." // where the previous element is not a link. UnixPath result = fs.rootDirectory(); for (int i=0; i<absolute.getNameCount(); i++) { UnixPath element = absolute.getName(i); // eliminate "." if ((element.asByteArray().length == 1) && (element.asByteArray()[0] == '.')) continue; // cannot eliminate ".." if previous element is a link if ((element.asByteArray().length == 2) && (element.asByteArray()[0] == '.') && (element.asByteArray()[1] == '.')) { UnixFileAttributes attrs = null; try { attrs = UnixFileAttributes.get(result, false); } catch (UnixException x) { x.rethrowAsIOException(result); } if (!attrs.isSymbolicLink()) { result = result.getParent(); if (result == null) { result = fs.rootDirectory(); } continue; } } result = result.resolve(element); } // check file exists (without following links) try { UnixFileAttributes.get(result, false); } catch (UnixException x) { x.rethrowAsIOException(result); } return result; } @Override public URI toUri() { return UnixUriUtils.toUri(this); } @Override public WatchKey register(WatchService watcher, WatchEvent.Kind<?>[] events, WatchEvent.Modifier... modifiers) throws IOException { if (watcher == null) throw new NullPointerException(); if (!(watcher instanceof AbstractWatchService)) throw new ProviderMismatchException(); checkRead(); return ((AbstractWatchService)watcher).register(this, events, modifiers); } }