/*

* Copyright 2012 The Netty Project

*

* The Netty Project licenses this file to you under the Apache License,

* version 2.0 (the "License"); you may not use this file except in compliance

* with the License. You may obtain a copy of the License at:

*

* http://www.apache.org/licenses/LICENSE-2.0

*

* Unless required by applicable law or agreed to in writing, software

* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT

* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the

* License for the specific language governing permissions and limitations

* under the License.

*/

package io.netty.buffer;

import io.netty.util.CharsetUtil;

import java.nio.ByteBuffer;

import java.nio.ByteOrder;

import java.nio.CharBuffer;

import java.nio.charset.CharacterCodingException;

import java.nio.charset.Charset;

import java.nio.charset.CharsetDecoder;

import java.nio.charset.CharsetEncoder;

import java.nio.charset.CoderResult;

/**

* A collection of utility methods that is related with handling {@link ByteBuf}.

*/

public final class ByteBufUtil {

private static final char[] HEXDUMP_TABLE = new char[256 * 4];

static {

final char[] DIGITS = "0123456789abcdef".toCharArray();

for (int i = 0; i < 256; i ++) {

HEXDUMP_TABLE[ i << 1 ] = DIGITS[i >>> 4 & 0x0F];

HEXDUMP_TABLE[(i << 1) + 1] = DIGITS[i & 0x0F];

}

}

/**

* Returns a <a href="http://en.wikipedia.org/wiki/Hex_dump">hex dump</a>

* of the specified buffer's readable bytes.

*/

public static String hexDump(ByteBuf buffer) {

return hexDump(buffer, buffer.readerIndex(), buffer.readableBytes());

}

/**

* Returns a <a href="http://en.wikipedia.org/wiki/Hex_dump">hex dump</a>

* of the specified buffer's sub-region.

*/

public static String hexDump(ByteBuf buffer, int fromIndex, int length) {

if (length < 0) {

throw new IllegalArgumentException("length: " + length);

}

if (length == 0) {

return "";

}

int endIndex = fromIndex + length;

char[] buf = new char[length << 1];

int srcIdx = fromIndex;

int dstIdx = 0;

for (; srcIdx < endIndex; srcIdx ++, dstIdx += 2) {

System.arraycopy(

HEXDUMP_TABLE, buffer.getUnsignedByte(srcIdx) << 1,

buf, dstIdx, 2);

}

return new String(buf);

}

/**

* Returns a <a href="http://en.wikipedia.org/wiki/Hex_dump">hex dump</a>

* of the specified byte array.

*/

public static String hexDump(byte[] array) {

return hexDump(array, 0, array.length);

}

/**

* Returns a <a href="http://en.wikipedia.org/wiki/Hex_dump">hex dump</a>

* of the specified byte array's sub-region.

*/

public static String hexDump(byte[] array, int fromIndex, int length) {

if (length < 0) {

throw new IllegalArgumentException("length: " + length);

}

if (length == 0) {

return "";

}

int endIndex = fromIndex + length;

char[] buf = new char[length << 1];

int srcIdx = fromIndex;

int dstIdx = 0;

for (; srcIdx < endIndex; srcIdx ++, dstIdx += 2) {

System.arraycopy(HEXDUMP_TABLE, (array[srcIdx] & 0xFF) << 1, buf, dstIdx, 2);

}

return new String(buf);

}

/**

* Calculates the hash code of the specified buffer. This method is

* useful when implementing a new buffer type.

*/

public static int hashCode(ByteBuf buffer) {

final int aLen = buffer.readableBytes();

final int intCount = aLen >>> 2;

final int byteCount = aLen & 3;

int hashCode = 1;

int arrayIndex = buffer.readerIndex();

if (buffer.order() == ByteOrder.BIG_ENDIAN) {

for (int i = intCount; i > 0; i --) {

hashCode = 31 * hashCode + buffer.getInt(arrayIndex);

arrayIndex += 4;

}

} else {

for (int i = intCount; i > 0; i --) {

hashCode = 31 * hashCode + swapInt(buffer.getInt(arrayIndex));

arrayIndex += 4;

}

}

for (int i = byteCount; i > 0; i --) {

hashCode = 31 * hashCode + buffer.getByte(arrayIndex ++);

}

if (hashCode == 0) {

hashCode = 1;

}

return hashCode;

}

/**

* Returns {@code true} if and only if the two specified buffers are

* identical to each other as described in {@code ChannelBuffer#equals(Object)}.

* This method is useful when implementing a new buffer type.

*/

public static boolean equals(ByteBuf bufferA, ByteBuf bufferB) {

final int aLen = bufferA.readableBytes();

if (aLen != bufferB.readableBytes()) {

return false;

}

final int longCount = aLen >>> 3;

final int byteCount = aLen & 7;

int aIndex = bufferA.readerIndex();

int bIndex = bufferB.readerIndex();

if (bufferA.order() == bufferB.order()) {

for (int i = longCount; i > 0; i --) {

if (bufferA.getLong(aIndex) != bufferB.getLong(bIndex)) {

return false;

}

aIndex += 8;

bIndex += 8;

}

} else {

for (int i = longCount; i > 0; i --) {

if (bufferA.getLong(aIndex) != swapLong(bufferB.getLong(bIndex))) {

return false;

}

aIndex += 8;

bIndex += 8;

}

}

for (int i = byteCount; i > 0; i --) {

if (bufferA.getByte(aIndex) != bufferB.getByte(bIndex)) {

return false;

}

aIndex ++;

bIndex ++;

}

return true;

}

/**

* Compares the two specified buffers as described in {@link ByteBuf#compareTo(ByteBuf)}.

* This method is useful when implementing a new buffer type.

*/

public static int compare(ByteBuf bufferA, ByteBuf bufferB) {

final int aLen = bufferA.readableBytes();

final int bLen = bufferB.readableBytes();

final int minLength = Math.min(aLen, bLen);

final int uintCount = minLength >>> 2;

final int byteCount = minLength & 3;

int aIndex = bufferA.readerIndex();

int bIndex = bufferB.readerIndex();

if (bufferA.order() == bufferB.order()) {

for (int i = uintCount; i > 0; i --) {

long va = bufferA.getUnsignedInt(aIndex);

long vb = bufferB.getUnsignedInt(bIndex);

if (va > vb) {

return 1;

}

if (va < vb) {

return -1;

}

aIndex += 4;

bIndex += 4;

}

} else {

for (int i = uintCount; i > 0; i --) {

long va = bufferA.getUnsignedInt(aIndex);

long vb = swapInt(bufferB.getInt(bIndex)) & 0xFFFFFFFFL;

if (va > vb) {

return 1;

}

if (va < vb) {

return -1;

}

aIndex += 4;

bIndex += 4;

}

}

for (int i = byteCount; i > 0; i --) {

short va = bufferA.getUnsignedByte(aIndex);

short vb = bufferB.getUnsignedByte(bIndex);

if (va > vb) {

return 1;

}

if (va < vb) {

return -1;

}

aIndex ++;

bIndex ++;

}

return aLen - bLen;

}

/**

* The default implementation of {@link ByteBuf#indexOf(int, int, byte)}.

* This method is useful when implementing a new buffer type.

*/

public static int indexOf(ByteBuf buffer, int fromIndex, int toIndex, byte value) {

if (fromIndex <= toIndex) {

return firstIndexOf(buffer, fromIndex, toIndex, value);

} else {

return lastIndexOf(buffer, fromIndex, toIndex, value);

}

}

/**

* Toggles the endianness of the specified 16-bit short integer.

*/

public static short swapShort(short value) {

return Short.reverseBytes(value);

}

/**

* Toggles the endianness of the specified 24-bit medium integer.

*/

public static int swapMedium(int value) {

int swapped = value << 16 & 0xff0000 | value & 0xff00 | value >>> 16 & 0xff;

if ((swapped & 0x800000) != 0) {

swapped |= 0xff000000;

}

return swapped;

}

/**

* Toggles the endianness of the specified 32-bit integer.

*/

public static int swapInt(int value) {

return Integer.reverseBytes(value);

}

/**

* Toggles the endianness of the specified 64-bit long integer.

*/

public static long swapLong(long value) {

return Long.reverseBytes(value);

}

/**

* Read the given amount of bytes into a new {@link ByteBuf} that is allocated from the {@link ByteBufAllocator}.

*/

public static ByteBuf readBytes(ByteBufAllocator alloc, ByteBuf buffer, int length) {

boolean release = true;

ByteBuf dst = alloc.buffer(length);

try {

buffer.readBytes(dst);

release = false;

return dst;

} finally {

if (release) {

dst.release();

}

}

}

private static int firstIndexOf(ByteBuf buffer, int fromIndex, int toIndex, byte value) {

fromIndex = Math.max(fromIndex, 0);

if (fromIndex >= toIndex || buffer.capacity() == 0) {

return -1;

}

for (int i = fromIndex; i < toIndex; i ++) {

if (buffer.getByte(i) == value) {

return i;

}

}

return -1;

}

private static int lastIndexOf(ByteBuf buffer, int fromIndex, int toIndex, byte value) {

fromIndex = Math.min(fromIndex, buffer.capacity());

if (fromIndex < 0 || buffer.capacity() == 0) {

return -1;

}

for (int i = fromIndex - 1; i >= toIndex; i --) {

if (buffer.getByte(i) == value) {

return i;

}

}

return -1;

}

/**

* Encode the given {@link CharBuffer} using the given {@link Charset} into a new {@link ByteBuf} which

* is allocated via the {@link ByteBufAllocator}.

*/

public static ByteBuf encodeString(ByteBufAllocator alloc, CharBuffer src, Charset charset) {

final CharsetEncoder encoder = CharsetUtil.getEncoder(charset);

int length = (int) ((double) src.remaining() * encoder.maxBytesPerChar());

boolean release = true;

final ByteBuf dst = alloc.buffer(length);

try {

final ByteBuffer dstBuf = dst.internalNioBuffer(0, length);

final int pos = dstBuf.position();

CoderResult cr = encoder.encode(src, dstBuf, true);

if (!cr.isUnderflow()) {

cr.throwException();

}

cr = encoder.flush(dstBuf);

if (!cr.isUnderflow()) {

cr.throwException();

}

dst.writerIndex(dst.writerIndex() + dstBuf.position() - pos);

release = false;

return dst;

} catch (CharacterCodingException x) {

throw new IllegalStateException(x);

} finally {

if (release) {

dst.release();

}

}

}

static String decodeString(ByteBuffer src, Charset charset) {

final CharsetDecoder decoder = CharsetUtil.getDecoder(charset);

final CharBuffer dst = CharBuffer.allocate(

(int) ((double) src.remaining() * decoder.maxCharsPerByte()));

try {

CoderResult cr = decoder.decode(src, dst, true);

if (!cr.isUnderflow()) {

cr.throwException();

}

cr = decoder.flush(dst);

if (!cr.isUnderflow()) {

cr.throwException();

}

} catch (CharacterCodingException x) {

throw new IllegalStateException(x);

}

return dst.flip().toString();

}

private ByteBufUtil() { }

}