Mercurial > hg > icedtea7-forest > jdk
view src/share/classes/sun/security/provider/ByteArrayAccess.java @ 9251:85bcd2abf0a2
Merge jdk7u151-b01
| author | andrew |
|---|---|
| date | Tue, 22 Aug 2017 02:03:52 +0100 |
| parents | a3efeb9f5fdb eeb56f4c36b1 |
| children |
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/* * Copyright (c) 2006, 2015, 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.security.provider; import static java.lang.Integer.reverseBytes; import static java.lang.Long.reverseBytes; import java.nio.ByteOrder; import sun.misc.Unsafe; /** * Optimized methods for converting between byte[] and int[]/long[], both for * big endian and little endian byte orders. * * Currently, it includes a default code path plus two optimized code paths. * One is for little endian architectures that support full speed int/long * access at unaligned addresses (i.e. x86/amd64). The second is for big endian * architectures (that only support correctly aligned access), such as SPARC. * These are the only platforms we currently support, but other optimized * variants could be added as needed. * * NOTE that ArrayIndexOutOfBoundsException will be thrown if the bounds checks * failed. * * This class may also be helpful in improving the performance of the * crypto code in the SunJCE provider. However, for now it is only accessible by * the message digest implementation in the SUN provider. * * @since 1.6 * @author Andreas Sterbenz */ final class ByteArrayAccess { private ByteArrayAccess() { // empty } private static final Unsafe unsafe = Unsafe.getUnsafe(); // whether to use the optimized path for little endian platforms that // support full speed unaligned memory access. private static final boolean littleEndianUnaligned; // whether to use the optimzied path for big endian platforms that // support only correctly aligned full speed memory access. // (Note that on SPARC unaligned memory access is possible, but it is // implemented using a software trap and therefore very slow) private static final boolean bigEndian; private final static int byteArrayOfs = unsafe.arrayBaseOffset(byte[].class); static { boolean scaleOK = ((unsafe.arrayIndexScale(byte[].class) == 1) && (unsafe.arrayIndexScale(int[].class) == 4) && (unsafe.arrayIndexScale(long[].class) == 8) && ((byteArrayOfs & 3) == 0)); ByteOrder byteOrder = ByteOrder.nativeOrder(); littleEndianUnaligned = scaleOK && unaligned() && (byteOrder == ByteOrder.LITTLE_ENDIAN); bigEndian = scaleOK && (byteOrder == ByteOrder.BIG_ENDIAN); } // Return whether this platform supports full speed int/long memory access // at unaligned addresses. private static boolean unaligned() { return unsafe.unalignedAccess(); } /** * byte[] to int[] conversion, little endian byte order. */ static void b2iLittle(byte[] in, int inOfs, int[] out, int outOfs, int len) { if ((inOfs < 0) || ((in.length - inOfs) < len) || (outOfs < 0) || ((out.length - outOfs) < len/4)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { inOfs += byteArrayOfs; len += inOfs; while (inOfs < len) { out[outOfs++] = unsafe.getInt(in, (long)inOfs); inOfs += 4; } } else if (bigEndian && ((inOfs & 3) == 0)) { inOfs += byteArrayOfs; len += inOfs; while (inOfs < len) { out[outOfs++] = reverseBytes(unsafe.getInt(in, (long)inOfs)); inOfs += 4; } } else { len += inOfs; while (inOfs < len) { out[outOfs++] = ((in[inOfs ] & 0xff) ) | ((in[inOfs + 1] & 0xff) << 8) | ((in[inOfs + 2] & 0xff) << 16) | ((in[inOfs + 3] ) << 24); inOfs += 4; } } } // Special optimization of b2iLittle(in, inOfs, out, 0, 64) static void b2iLittle64(byte[] in, int inOfs, int[] out) { if ((inOfs < 0) || ((in.length - inOfs) < 64) || (out.length < 16)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { inOfs += byteArrayOfs; out[ 0] = unsafe.getInt(in, (long)(inOfs )); out[ 1] = unsafe.getInt(in, (long)(inOfs + 4)); out[ 2] = unsafe.getInt(in, (long)(inOfs + 8)); out[ 3] = unsafe.getInt(in, (long)(inOfs + 12)); out[ 4] = unsafe.getInt(in, (long)(inOfs + 16)); out[ 5] = unsafe.getInt(in, (long)(inOfs + 20)); out[ 6] = unsafe.getInt(in, (long)(inOfs + 24)); out[ 7] = unsafe.getInt(in, (long)(inOfs + 28)); out[ 8] = unsafe.getInt(in, (long)(inOfs + 32)); out[ 9] = unsafe.getInt(in, (long)(inOfs + 36)); out[10] = unsafe.getInt(in, (long)(inOfs + 40)); out[11] = unsafe.getInt(in, (long)(inOfs + 44)); out[12] = unsafe.getInt(in, (long)(inOfs + 48)); out[13] = unsafe.getInt(in, (long)(inOfs + 52)); out[14] = unsafe.getInt(in, (long)(inOfs + 56)); out[15] = unsafe.getInt(in, (long)(inOfs + 60)); } else if (bigEndian && ((inOfs & 3) == 0)) { inOfs += byteArrayOfs; out[ 0] = reverseBytes(unsafe.getInt(in, (long)(inOfs ))); out[ 1] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 4))); out[ 2] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 8))); out[ 3] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 12))); out[ 4] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 16))); out[ 5] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 20))); out[ 6] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 24))); out[ 7] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 28))); out[ 8] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 32))); out[ 9] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 36))); out[10] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 40))); out[11] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 44))); out[12] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 48))); out[13] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 52))); out[14] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 56))); out[15] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 60))); } else { b2iLittle(in, inOfs, out, 0, 64); } } /** * int[] to byte[] conversion, little endian byte order. */ static void i2bLittle(int[] in, int inOfs, byte[] out, int outOfs, int len) { if ((inOfs < 0) || ((in.length - inOfs) < len/4) || (outOfs < 0) || ((out.length - outOfs) < len)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { outOfs += byteArrayOfs; len += outOfs; while (outOfs < len) { unsafe.putInt(out, (long)outOfs, in[inOfs++]); outOfs += 4; } } else if (bigEndian && ((outOfs & 3) == 0)) { outOfs += byteArrayOfs; len += outOfs; while (outOfs < len) { unsafe.putInt(out, (long)outOfs, reverseBytes(in[inOfs++])); outOfs += 4; } } else { len += outOfs; while (outOfs < len) { int i = in[inOfs++]; out[outOfs++] = (byte)(i ); out[outOfs++] = (byte)(i >> 8); out[outOfs++] = (byte)(i >> 16); out[outOfs++] = (byte)(i >> 24); } } } // Store one 32-bit value into out[outOfs..outOfs+3] in little endian order. static void i2bLittle4(int val, byte[] out, int outOfs) { if ((outOfs < 0) || ((out.length - outOfs) < 4)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { unsafe.putInt(out, (long)(byteArrayOfs + outOfs), val); } else if (bigEndian && ((outOfs & 3) == 0)) { unsafe.putInt(out, (long)(byteArrayOfs + outOfs), reverseBytes(val)); } else { out[outOfs ] = (byte)(val ); out[outOfs + 1] = (byte)(val >> 8); out[outOfs + 2] = (byte)(val >> 16); out[outOfs + 3] = (byte)(val >> 24); } } /** * byte[] to int[] conversion, big endian byte order. */ static void b2iBig(byte[] in, int inOfs, int[] out, int outOfs, int len) { if ((inOfs < 0) || ((in.length - inOfs) < len) || (outOfs < 0) || ((out.length - outOfs) < len/4)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { inOfs += byteArrayOfs; len += inOfs; while (inOfs < len) { out[outOfs++] = reverseBytes(unsafe.getInt(in, (long)inOfs)); inOfs += 4; } } else if (bigEndian && ((inOfs & 3) == 0)) { inOfs += byteArrayOfs; len += inOfs; while (inOfs < len) { out[outOfs++] = unsafe.getInt(in, (long)inOfs); inOfs += 4; } } else { len += inOfs; while (inOfs < len) { out[outOfs++] = ((in[inOfs + 3] & 0xff) ) | ((in[inOfs + 2] & 0xff) << 8) | ((in[inOfs + 1] & 0xff) << 16) | ((in[inOfs ] ) << 24); inOfs += 4; } } } // Special optimization of b2iBig(in, inOfs, out, 0, 64) static void b2iBig64(byte[] in, int inOfs, int[] out) { if ((inOfs < 0) || ((in.length - inOfs) < 64) || (out.length < 16)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { inOfs += byteArrayOfs; out[ 0] = reverseBytes(unsafe.getInt(in, (long)(inOfs ))); out[ 1] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 4))); out[ 2] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 8))); out[ 3] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 12))); out[ 4] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 16))); out[ 5] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 20))); out[ 6] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 24))); out[ 7] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 28))); out[ 8] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 32))); out[ 9] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 36))); out[10] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 40))); out[11] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 44))); out[12] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 48))); out[13] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 52))); out[14] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 56))); out[15] = reverseBytes(unsafe.getInt(in, (long)(inOfs + 60))); } else if (bigEndian && ((inOfs & 3) == 0)) { inOfs += byteArrayOfs; out[ 0] = unsafe.getInt(in, (long)(inOfs )); out[ 1] = unsafe.getInt(in, (long)(inOfs + 4)); out[ 2] = unsafe.getInt(in, (long)(inOfs + 8)); out[ 3] = unsafe.getInt(in, (long)(inOfs + 12)); out[ 4] = unsafe.getInt(in, (long)(inOfs + 16)); out[ 5] = unsafe.getInt(in, (long)(inOfs + 20)); out[ 6] = unsafe.getInt(in, (long)(inOfs + 24)); out[ 7] = unsafe.getInt(in, (long)(inOfs + 28)); out[ 8] = unsafe.getInt(in, (long)(inOfs + 32)); out[ 9] = unsafe.getInt(in, (long)(inOfs + 36)); out[10] = unsafe.getInt(in, (long)(inOfs + 40)); out[11] = unsafe.getInt(in, (long)(inOfs + 44)); out[12] = unsafe.getInt(in, (long)(inOfs + 48)); out[13] = unsafe.getInt(in, (long)(inOfs + 52)); out[14] = unsafe.getInt(in, (long)(inOfs + 56)); out[15] = unsafe.getInt(in, (long)(inOfs + 60)); } else { b2iBig(in, inOfs, out, 0, 64); } } /** * int[] to byte[] conversion, big endian byte order. */ static void i2bBig(int[] in, int inOfs, byte[] out, int outOfs, int len) { if ((inOfs < 0) || ((in.length - inOfs) < len/4) || (outOfs < 0) || ((out.length - outOfs) < len)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { outOfs += byteArrayOfs; len += outOfs; while (outOfs < len) { unsafe.putInt(out, (long)outOfs, reverseBytes(in[inOfs++])); outOfs += 4; } } else if (bigEndian && ((outOfs & 3) == 0)) { outOfs += byteArrayOfs; len += outOfs; while (outOfs < len) { unsafe.putInt(out, (long)outOfs, in[inOfs++]); outOfs += 4; } } else { len += outOfs; while (outOfs < len) { int i = in[inOfs++]; out[outOfs++] = (byte)(i >> 24); out[outOfs++] = (byte)(i >> 16); out[outOfs++] = (byte)(i >> 8); out[outOfs++] = (byte)(i ); } } } // Store one 32-bit value into out[outOfs..outOfs+3] in big endian order. static void i2bBig4(int val, byte[] out, int outOfs) { if ((outOfs < 0) || ((out.length - outOfs) < 4)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { unsafe.putInt(out, (long)(byteArrayOfs + outOfs), reverseBytes(val)); } else if (bigEndian && ((outOfs & 3) == 0)) { unsafe.putInt(out, (long)(byteArrayOfs + outOfs), val); } else { out[outOfs ] = (byte)(val >> 24); out[outOfs + 1] = (byte)(val >> 16); out[outOfs + 2] = (byte)(val >> 8); out[outOfs + 3] = (byte)(val ); } } /** * byte[] to long[] conversion, big endian byte order. */ static void b2lBig(byte[] in, int inOfs, long[] out, int outOfs, int len) { if ((inOfs < 0) || ((in.length - inOfs) < len) || (outOfs < 0) || ((out.length - outOfs) < len/8)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { inOfs += byteArrayOfs; len += inOfs; while (inOfs < len) { out[outOfs++] = reverseBytes(unsafe.getLong(in, (long)inOfs)); inOfs += 8; } } else if (bigEndian && ((inOfs & 3) == 0)) { // In the current HotSpot memory layout, the first element of a // byte[] is only 32-bit aligned, not 64-bit. // That means we could use getLong() only for offset 4, 12, etc., // which would rarely occur in practice. Instead, we use an // optimization that uses getInt() so that it works for offset 0. inOfs += byteArrayOfs; len += inOfs; while (inOfs < len) { out[outOfs++] = ((long)unsafe.getInt(in, (long)inOfs) << 32) | (unsafe.getInt(in, (long)(inOfs + 4)) & 0xffffffffL); inOfs += 8; } } else { len += inOfs; while (inOfs < len) { int i1 = ((in[inOfs + 3] & 0xff) ) | ((in[inOfs + 2] & 0xff) << 8) | ((in[inOfs + 1] & 0xff) << 16) | ((in[inOfs ] ) << 24); inOfs += 4; int i2 = ((in[inOfs + 3] & 0xff) ) | ((in[inOfs + 2] & 0xff) << 8) | ((in[inOfs + 1] & 0xff) << 16) | ((in[inOfs ] ) << 24); out[outOfs++] = ((long)i1 << 32) | (i2 & 0xffffffffL); inOfs += 4; } } } // Special optimization of b2lBig(in, inOfs, out, 0, 128) static void b2lBig128(byte[] in, int inOfs, long[] out) { if ((inOfs < 0) || ((in.length - inOfs) < 128) || (out.length < 16)) { throw new ArrayIndexOutOfBoundsException(); } if (littleEndianUnaligned) { inOfs += byteArrayOfs; out[ 0] = reverseBytes(unsafe.getLong(in, (long)(inOfs ))); out[ 1] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 8))); out[ 2] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 16))); out[ 3] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 24))); out[ 4] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 32))); out[ 5] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 40))); out[ 6] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 48))); out[ 7] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 56))); out[ 8] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 64))); out[ 9] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 72))); out[10] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 80))); out[11] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 88))); out[12] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 96))); out[13] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 104))); out[14] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 112))); out[15] = reverseBytes(unsafe.getLong(in, (long)(inOfs + 120))); } else { // no optimization for big endian, see comments in b2lBig b2lBig(in, inOfs, out, 0, 128); } } /** * long[] to byte[] conversion, big endian byte order. */ static void l2bBig(long[] in, int inOfs, byte[] out, int outOfs, int len) { if ((inOfs < 0) || ((in.length - inOfs) < len/8) || (outOfs < 0) || ((out.length - outOfs) < len)) { throw new ArrayIndexOutOfBoundsException(); } len += outOfs; while (outOfs < len) { long i = in[inOfs++]; out[outOfs++] = (byte)(i >> 56); out[outOfs++] = (byte)(i >> 48); out[outOfs++] = (byte)(i >> 40); out[outOfs++] = (byte)(i >> 32); out[outOfs++] = (byte)(i >> 24); out[outOfs++] = (byte)(i >> 16); out[outOfs++] = (byte)(i >> 8); out[outOfs++] = (byte)(i ); } } }