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DirectByteBuffer简介

    博客分类:
  • NIO
nio 
阅读更多
Java NIO ByteBuffer详解:http://donald-draper.iteye.com/blog/2357084
MappedByteBuffer定义:http://donald-draper.iteye.com/blog/2371594
Reference定义(PhantomReference,Cleaner):http://donald-draper.iteye.com/blog/2371661
ByteBuffer有两个实现一个为,HeapByteBuffer,另一个为DirectByteBuffer,
在上一篇文章中我们看了HeapByteBuffer,今天来看另外一个DirectByteBuffer。
下面是两种ByteBuffer创建的方法:
1.HeapByteBuffer
//ByteBuffer,创建HeapByteBuffer方法
 public static ByteBuffer allocate(int capacity) {
        if (capacity < 0)
            throw new IllegalArgumentException();
        return new HeapByteBuffer(capacity, capacity);
    }

HeapByteBuffer使用的java堆内存
2.DirectByteBuffer
//ByteBuffer,创建DirectByteBuffer方法
public static ByteBuffer allocateDirect(int capacity) {
        return new DirectByteBuffer(capacity);
    }

为了更好的理解两者的区别,先来读一下ByteBuffer的java doc
/*<a name="direct">
 * <h4> Direct <i>vs.</i> non-direct buffers </h4>
 *
 * <p> A byte buffer is either <i>direct</i> or <i>non-direct</i>.  Given a
 * direct byte buffer, the Java virtual machine will make a best effort to
 * perform native I/O operations directly upon it.  That is, it will attempt to
 * avoid copying the buffer's content to (or from) an intermediate buffer
 * before (or after) each invocation of one of the underlying operating
 * system's native I/O operations.
 *ByteBuffer有direct(DirectByteBuffer)和non-direct(HeapByteBuffer)两种。
 Java虚拟机将会直接依赖于direct类型的ByteBuffer,尽最大努力执行本地的IO操作。
在进行系统底层的IO操作前或后,尝试避免直接拷贝buffer。
 * <p> A direct byte buffer may be created by invoking the {@link
 * #allocateDirect(int) allocateDirect} factory method of this class.  The
 * buffers returned by this method typically have somewhat higher allocation
 * and deallocation costs than non-direct buffers.  The contents of direct
 * buffers may reside outside of the normal garbage-collected heap, and so
 * their impact upon the memory footprint of an application might not be
 * obvious.  It is therefore recommended that direct buffers be allocated
 * primarily for large, long-lived buffers that are subject to the underlying
 * system's native I/O operations.  In general it is best to allocate direct
 * buffers only when they yield a measureable gain in program performance.
 *direct类型的buffer通过allocateDirect(int)方法创建。direct类型的buffer分配空间和
 重新分配空间,比non-direct类型的buffer代价某种程度上要高。由于direct类型的buffer的内容存储在正常的可回收垃圾的堆之外,所以对应用的内存使用影响不是太明显。因此强烈建议将direct类型buffer初始化分配足够大&long-lived的空间,以便底层操作系统的IO操作。如果对应用性能有一个客观的提升,则最好使用#allocateDirect(int)创建一个DirectByteBuffer。
 * <p> A direct byte buffer may also be created by {@link
 * java.nio.channels.FileChannel#map </code>mapping<code>} a region of a file
 * directly into memory.  An implementation of the Java platform may optionally
 * support the creation of direct byte buffers from native code via JNI.  If an
 * instance of one of these kinds of buffers refers to an inaccessible region
 * of memory then an attempt to access that region will not change the buffer's
 * content and will cause an unspecified exception to be thrown either at the
 * time of the access or at some later time.
 *一个direct类型buffer,亦可以通过java.nio.channels.FileChannel#map创建,映射文件
直接到内存一个region。Java平台的具体实现可以选择通过JNI调用本地代码创建一个direct类型buffer。如果direct类型buffer一个具体实例引用不可访问的内存region,尝试访问region,不会改变buffer的内容,无论在访问的时间,还是访问后,将会引起一个不确定的异常抛出。
 * <p> Whether a byte buffer is direct or non-direct may be determined by
 * invoking its {@link #isDirect isDirect} method.  This method is provided so
 * that explicit buffer management can be done in performance-critical code.
 *是不是direct类型的buffer,我们可以通过#isDirect方法来确定。
*/

从上面一段话可以看出, DirectByteBuffer的字节直接存放在内存中,对提升底层IO操作的性能有利,由于DirectByteBuffer的字节直接存放在内存中,并不会影响应用的堆内存。HeapByteBuffer的字节,则是存放在 Java堆内存中。DirectByteBuffer主要用于Java NIO包中一些又进行底层IO操作的通道(SocketChannel,FileChannel等)。
package java.nio;
import java.io.FileDescriptor;
import sun.misc.Cleaner;
import sun.misc.Unsafe;
import sun.misc.VM;
import sun.nio.ch.DirectBuffer;
class DirectByteBuffer
    extends MappedByteBuffer
    implements DirectBuffer
{
    // Cached unsafe-access object,缓存安全访问对象
    protected static final Unsafe unsafe = Bits.unsafe();

    // Cached array base offset,缓存数据开始位置
    private static final long arrayBaseOffset = (long)unsafe.arrayBaseOffset(byte[].class);

    // Cached unaligned-access capability 这个的含义不是太清楚,有知道的可以留言给我,谢谢
    protected static final boolean unaligned = Bits.unaligned();

    // Base address, used in all indexing calculations
    // NOTE: moved up to Buffer.java for speed in JNI GetDirectBufferAddress
    //    protected long address;

    // An object attached to this buffer. If this buffer is a view of another
    // buffer then we use this field to keep a reference to that buffer to
    // ensure that its memory isn't freed before we are done with it.
    //att为缓冲的附加物。如果缓存是两一个缓存的视图,我们可以用att标记参考的buffer,
    //以确保参与buffer的内存在我们用之前不会释放。
    private final Object att;
    //清除引用对象cleaner
    private final Cleaner cleaner;
}

我们来看一下这个unaligned的含义:
 protected static final boolean unaligned = Bits.unaligned();

//Bits
private static boolean unaligned;
private static boolean unalignedKnown = false;
 static boolean unaligned() {
     if (unalignedKnown)
         return unaligned;
     String arch = AccessController.doPrivileged(
         new sun.security.action.GetPropertyAction("os.arch"));
     unaligned = arch.equals("i386") || arch.equals("x86")
         || arch.equals("amd64") || arch.equals("x86_64");
     unalignedKnown = true;
     return unaligned;
 }

从Bits的unaligned我们大致可以猜出unaligned的含义,为操作系统架构是否为已知;以便我们在已知的架构下,操作物理内存。
我们来看一下DirectByteBuffer的构造
// Primary constructor
 DirectByteBuffer(int cap) {                   // package-private

     super(-1, 0, cap, cap);
     //获取系统内存使用是否分页
     boolean pa = VM.isDirectMemoryPageAligned();
     //获取分页size
     int ps = Bits.pageSize();
     //确定分页size
     long size = Math.max(1L, (long)cap + (pa ? ps : 0));
     //预留内存
     Bits.reserveMemory(size, cap);

     long base = 0;
     try {
         //分配内存
         base = unsafe.allocateMemory(size);
     } catch (OutOfMemoryError x) {
         //释放预留内存
         Bits.unreserveMemory(size, cap);
         throw x;
     }
     //设置安全访问对象unsafe的起始位置
     unsafe.setMemory(base, size, (byte) 0);
     //设置缓存的起始位置
     if (pa && (base % ps != 0)) {
         // Round up to page boundary
         address = base + ps - (base & (ps - 1));
     } else {
         address = base;
     }
     //创建buffer的Cleaner
     cleaner = Cleaner.create(this, new Deallocator(base, size, cap));
     att = null;
}

DirectByteBuffer的构造有几点我们要关注:
1.
 //获取系统内存使用是否分页
 boolean pa = VM.isDirectMemoryPageAligned();

2.
 //预留内存
 Bits.reserveMemory(size, cap);

3.
//分配内存
 base = unsafe.allocateMemory(size);

4.
 //释放预留内存
 Bits.unreserveMemory(size, cap);

5.
 //设置安全访问对象unsafe的起始位置
 unsafe.setMemory(base, size, (byte) 0);


6.
//设置缓存的起始位置
     if (pa && (base % ps != 0)) {
         // Round up to page boundary
         address = base + ps - (base & (ps - 1));
     } else {
         address = base;
     }

7.
 //创建buffer的Cleaner
 cleaner = Cleaner.create(this, new Deallocator(base, size, cap))
;
下面分别来看这几点:
1.
 //获取系统内存使用是否分页
 boolean pa = VM.isDirectMemoryPageAligned();

//VM
private static boolean pageAlignDirectMemory;//内存是否分页
 public static boolean isDirectMemoryPageAligned()
    {
        return pageAlignDirectMemory;
    }
 public static void saveAndRemoveProperties(Properties properties)
    {
        if(booted)
            throw new IllegalStateException("System initialization has completed");
        savedProps.putAll(properties);
        String s = (String)properties.remove("sun.nio.MaxDirectMemorySize");
        if(s != null)
            if(s.equals("-1"))
            {
                directMemory = Runtime.getRuntime().maxMemory();
            } else
            {
                long l = Long.parseLong(s);
                if(l > -1L)
                    directMemory = l;
            }
	//如果系统属性中有sun.nio.PageAlignDirectMemory配置项,则pageAlignDirectMemory为true
        s = (String)properties.remove("sun.nio.PageAlignDirectMemory");
        if("true".equals(s))
            pageAlignDirectMemory = true;
        s = properties.getProperty("sun.lang.ClassLoader.allowArraySyntax");
        allowArraySyntax = s != null ? Boolean.parseBoolean(s) : defaultAllowArraySyntax;
        properties.remove("java.lang.Integer.IntegerCache.high");
        properties.remove("sun.zip.disableMemoryMapping");
        properties.remove("sun.java.launcher.diag");
    }

2.
//预留内存
 Bits.reserveMemory(size, cap);

//Bits
  
 private static volatile long maxMemory = VM.maxDirectMemory();//最大可用内存
    private static volatile long reservedMemory;//预留内存
    private static volatile long totalCapacity;//内存使用量
    private static volatile long count;
    private static boolean memoryLimitSet = false;

    // These methods should be called whenever direct memory is allocated or
    // freed.  They allow the user to control the amount of direct memory
    // which a process may access.  All sizes are specified in bytes.
    static void reserveMemory(long size, int cap) {
        synchronized (Bits.class) {
            if (!memoryLimitSet && VM.isBooted()) {
                maxMemory = VM.maxDirectMemory();
                memoryLimitSet = true;
            }
            // -XX:MaxDirectMemorySize limits the total capacity rather than the
            // actual memory usage, which will differ when buffers are page
            // aligned.
	    //如果有足够的内存可以使用,则更新预留内存和内存使用量
            if (cap <= maxMemory - totalCapacity) {
                reservedMemory += size;
                totalCapacity += cap;
                count++;
                return;
            }
        }
        //来及回收
        System.gc();
        try {
            Thread.sleep(100);
        } catch (InterruptedException x) {
            // Restore interrupt status
            Thread.currentThread().interrupt();
        }
        synchronized (Bits.class) {
	    //如果内存使用量+需要分配的内存容量超时最大内存使用量,则抛出OutOfMemoryError
            if (totalCapacity + cap > maxMemory)
                throw new OutOfMemoryError("Direct buffer memory");
            reservedMemory += size;
            totalCapacity += cap;
            count++;
        }

    }

3.
//分配内存
base = unsafe.allocateMemory(size);

//Unsafe
public native long allocateMemory(long l);

4.
//释放预留内存
 Bits.unreserveMemory(size, cap);

//Bits
//如果预留内存大于0,则释放预留内存,更新内存使用量
  static synchronized void unreserveMemory(long size, int cap) {
        if (reservedMemory > 0) {
            reservedMemory -= size;
            totalCapacity -= cap;
            count--;
            assert (reservedMemory > -1);
        }
    }

5.
  //设置安全访问对象unsafe的起始位置
unsafe.setMemory(base, size, (byte) 0);

//Unsafe
 
  public void setMemory(long l, long l1, byte byte0)
    {
        setMemory(null, l, l1, byte0);
    }
    public native void setMemory(Object obj, long l, long l1, byte byte0);


6.
 //设置缓存的起始位置
    if (pa && (base % ps != 0)) {
         // Round up to page boundary
         address = base + ps - (base & (ps - 1));
     } else {
         address = base;
     }

//Buffer
public abstract class Buffer {

    // Invariants: mark <= position <= limit <= capacity
    private int mark = -1;
    private int position = 0;
    private int limit;
    private int capacity;

    // Used only by direct buffers
    // NOTE: hoisted here for speed in JNI GetDirectBufferAddress
    //内存地址
    long address;
}

7.
 //创建buffer的Cleaner(清除引用对象cleaner)
cleaner = Cleaner.create(this, new Deallocator(base, size, cap));

再看这步之前,我们来看一下Deallocator
 private static class Deallocator
        implements Runnable
    {
        private static Unsafe unsafe = Unsafe.getUnsafe();
        private long address;
        private long size;
        private int capacity;

        private Deallocator(long address, long size, int capacity) {
            assert (address != 0);
            this.address = address;
            this.size = size;
            this.capacity = capacity;
        }
        public void run() {
            if (address == 0) {
                // Paranoia
                return;
            }
	    //释放内存
            unsafe.freeMemory(address);
            address = 0;
	    //释放预留内存
            Bits.unreserveMemory(size, capacity);
        }
}

在Reference定义(PhantomReference,Cleaner)这篇文章中,我们说过Cleaner清除引用对象的实际上是首先从引用对应队列ReferenceQueue移除引用对象,再执行清除线程thunk,完成实际的清除工作。
//Cleaner
private static final ReferenceQueue dummyQueue = new ReferenceQueue();
private static Cleaner first = null;
private Cleaner next;
private Cleaner prev;
private final Runnable thunk;
public void clean()
{
        if(!remove(this))
            return;
        try
        {
            thunk.run();
        }
	...
}

在DirectByteBuffer中Cleaner的thunk为Deallocator
从以上7步可以看,在DirectByteBuffer的构造主要是获取系统内存使用是否分页,预留内存,分配内存,设置安全访问对象unsafe的起始位置,设置缓存Buffer的起始位置address,创建buffer的Cleaner。
再看看其他的构造
// Invoked to construct a direct ByteBuffer referring to the block of
    // memory. A given arbitrary object may also be attached to the buffer.
    DirectByteBuffer(long addr, int cap, Object ob) {
       //ByteBuffer构造
        super(-1, 0, cap, cap);
        address = addr;
        cleaner = null;
        att = ob;
    }
    // Invoked only by JNI: NewDirectByteBuffer(void*, long)
    private DirectByteBuffer(long addr, int cap) {
        //ByteBuffer构造
        super(-1, 0, cap, cap);
        address = addr;
        cleaner = null;
        att = null;
    }
    上面这两的构造方法大同小异,
    // For memory-mapped buffers -- invoked by FileChannelImpl via reflection
    //此方法用于内存映射缓存,主要是FileChannelImpl通过反射调用
    protected DirectByteBuffer(int cap, long addr,
                                     FileDescriptor fd,
                                     Runnable unmapper)
    {
        //MappedByteBuffer构造
        super(-1, 0, cap, cap, fd);
        address = addr;
        cleaner = Cleaner.create(this, unmapper);
        att = null;
    }
    // For duplicates and slices,复制构造
    DirectByteBuffer(DirectBuffer db,         // package-private
                               int mark, int pos, int lim, int cap,
                               int off)
    {
        super(mark, pos, lim, cap);
	//定位起始地址
        address = db.address() + off;
        cleaner = null;
        att = db;
    }

来看其他方法
 //将DirectByteBuffer分割空间出来
 public ByteBuffer slice() {
        int pos = this.position();
        int lim = this.limit();
        assert (pos <= lim);
        int rem = (pos <= lim ? lim - pos : 0);
        int off = (pos << 0);
        assert (off >= 0);
        return new DirectByteBuffer(this, -1, 0, rem, rem, off);
    }
   //复制DirectByteBuffer
    public ByteBuffer duplicate() {
        return new DirectByteBuffer(this,
                                              this.markValue(),
                                              this.position(),
                                              this.limit(),
                                              this.capacity(),
                                              0);
    }
    //返回一个只读的DirectByteBufferR
     public ByteBuffer asReadOnlyBuffer() {
        return new DirectByteBufferR(this,
                                           this.markValue(),
                                           this.position(),
                                           this.limit(),
                                           this.capacity(),
                                           0);

    }

我们来看DirectByteBufferR的定义
class DirectByteBufferR
    extends DirectByteBuffer
    implements DirectBuffer
{
     DirectByteBufferR(int cap) {                   // package-private
        super(cap);
    }
     // For memory-mapped buffers -- invoked by FileChannelImpl via reflection
    //
    protected DirectByteBufferR(int cap, long addr,
                                     FileDescriptor fd,
                                     Runnable unmapper)
    {
        super(cap, addr, fd, unmapper);

    }
    // For duplicates and slices
    DirectByteBufferR(DirectBuffer db,         // package-private
                               int mark, int pos, int lim, int cap,
                               int off)
    {
        super(db, mark, pos, lim, cap, off);

    }
    //切割DirectByteBufferR剩余空间
     public ByteBuffer slice() {
        int pos = this.position();
        int lim = this.limit();
        assert (pos <= lim);
        int rem = (pos <= lim ? lim - pos : 0);
        int off = (pos << 0);
        assert (off >= 0);
        return new DirectByteBufferR(this, -1, 0, rem, rem, off);
    }
    //复制DirectByteBufferR
    public ByteBuffer duplicate() {
        return new DirectByteBufferR(this,
                                              this.markValue(),
                                              this.position(),
                                              this.limit(),
                                              this.capacity(),
                                              0);
    }
    //获取只读的DirectByteBufferR
    public ByteBuffer asReadOnlyBuffer() {
        return duplicate();
    }
     public ByteBuffer put(byte x) {
        throw new ReadOnlyBufferException();

    }
     public ByteBuffer put(ByteBuffer src) {
       throw new ReadOnlyBufferException();
     }
     public ByteBuffer put*(...) {
       throw new ReadOnlyBufferException();
     }
    //为Direct类型缓存区
    public boolean isDirect() {
        return true;
    }
    //只读
    public boolean isReadOnly() {
        return true;
    }
    /*相关的读操作与DirectByteBuffer基本相同*/
}

DirectByteBufferR为一个支持读操中的DirectByteBuffer,所有的写操作,将抛出ReadOnlyBufferException异常。
回到DirectByteBuffer的相关操作
//获取缓冲buffer起始地址
public long address() {
        return address;
    }
 //获取索引i对应的内存实际地址
 private long ix(int i) {
     return address + (i << 0);
 }

先来看put操作
//将byte放在position位置上
public ByteBuffer put(byte x) {
    unsafe.putByte(ix(nextPutIndex()), ((x)));
    return this;
}

//Buffer
//返回当前position位置,position位置自增
final int nextPutIndex() {                          // package-private
    if (position >= limit)
        throw new BufferOverflowException();
    return position++;
}


//将byte放在i位置上
public ByteBuffer put(int i, byte x) {
    unsafe.putByte(ix(checkIndex(i)), ((x)));
    return this;
}

//Buffer
//返回当前i位置是否有效
final int checkIndex(int i) {                       // package-private
    if ((i < 0) || (i >= limit))
        throw new IndexOutOfBoundsException();
    return i;
}

//读取Bufffer的数据,写到当前缓冲区中
public ByteBuffer put(ByteBuffer src) {
        //如果ByteBuffer为DirectByteBuffer
        if (src instanceof DirectByteBuffer) {
            if (src == this)
                throw new IllegalArgumentException();
            DirectByteBuffer sb = (DirectByteBuffer)src;
	    //在读buffer之前,要调用flip函数,所以position与limit数据,即为缓冲区真实数据
	    //这也是为什么在缓存区读写模式切换时,要调用flip函数的原因
	    //获取源DirectByteBuffer的position,limit
            int spos = sb.position();
            int slim = sb.limit();
            assert (spos <= slim);
	    //获取源DirectByteBuffer实际数据长度(buffer.flip())
            int srem = (spos <= slim ? slim - spos : 0);
            //获取当前DirectByteBuffer的position,limit
            int pos = position();
            int lim = limit();
            assert (pos <= lim);
	    //获取当前DirectByteBuffer剩余容量
            int rem = (pos <= lim ? lim - pos : 0);
            //如果当前buffer的剩余空间小于源buffer的数据长度,则抛出BufferOverflowException
            if (srem > rem)
                throw new BufferOverflowException();
            //copy源buffer到当前buffer
            unsafe.copyMemory(sb.ix(spos), ix(pos), srem << 0);
	    //重新定位源buffer和目的buffer的postion位置
            sb.position(spos + srem);
            position(pos + srem);
        } else if (src.hb != null) {
           //如果源buffer类型非DirectByteBuffer
            int spos = src.position();
            int slim = src.limit();
            assert (spos <= slim);
            int srem = (spos <= slim ? slim - spos : 0);
	    //读取源buffer的字节数组中数据,写到当前缓冲区
            put(src.hb, src.offset + spos, srem);
            src.position(spos + srem);

        } else {
	    //ByteBuffer
            super.put(src);
        }
        return this;
 }

put(ByteBuffer src) 有几点要看
1.
 //copy源buffer到当前buffer
  unsafe.copyMemory(sb.ix(spos), ix(pos), srem << 0);

2.
 //读取源buffer的字节数组中数据,写到当前缓冲区
  put(src.hb, src.offset + spos, srem);

我们分别来看这两点
1.
 //copy源buffer到当前buffer
  unsafe.copyMemory(sb.ix(spos), ix(pos), srem << 0);

//Unsafe
 public void copyMemory(long l, long l1, long l2)
    {
        copyMemory(null, l, null, l1, l2);
    }
public native void copyMemory(Object obj, long l, Object obj1, long l1, long l2);

2.
 //读取源buffer的字节数组中数据,写到当前缓冲区
  put(src.hb, src.offset + spos, srem);

//读取源buffer的字节数组中数据,写到当前缓冲区
  public ByteBuffer put(byte[] src, int offset, int length) {
        if ((length << 0) > Bits.JNI_COPY_FROM_ARRAY_THRESHOLD) {
            checkBounds(offset, length, src.length);
            int pos = position();
            int lim = limit();
            assert (pos <= lim);
	    //获取当前缓冲区剩余空间
            int rem = (pos <= lim ? lim - pos : 0);
            if (length > rem)
                throw new BufferOverflowException();
            Bits.copyFromArray(src, arrayBaseOffset, offset << 0,
                                   ix(pos), length << 0);
            //重新定位position
            position(pos + length);
        } else {
	    //ByteBuffer
            super.put(src, offset, length);
        }
        return this;
    }

//Bit
// These numbers represent the point at which we have empirically
// determined that the average cost of a JNI call exceeds the expense
// of an element by element copy.  These numbers may change over time.
//JNI字节数组拷贝临界条件
static final int JNI_COPY_TO_ARRAY_THRESHOLD   = 6;
static final int JNI_COPY_FROM_ARRAY_THRESHOLD = 6;

// This number limits the number of bytes to copy per call to Unsafe's
// copyMemory method. A limit is imposed to allow for safepoint polling
// during a large copy
//UNSAFE内存拷贝临界条件
static final long UNSAFE_COPY_THRESHOLD = 1024L * 1024L;
/**
     * Copy from given source array to destination address.
     *拷贝给定的字节数组到目的地址
     * @param   src
     *          source array
     * @param   srcBaseOffset
     *          offset of first element of storage in source array
     * @param   srcPos
     *          offset within source array of the first element to read
     * @param   dstAddr
     *          destination address
     * @param   length
     *          number of bytes to copy
     */
 static void copyFromArray(Object src, long srcBaseOffset, long srcPos,
                              long dstAddr, long length)
    {
        long offset = srcBaseOffset + srcPos;
        while (length > 0) {
            long size = (length > UNSAFE_COPY_THRESHOLD) ? UNSAFE_COPY_THRESHOLD : length;
            unsafe.copyMemory(src, offset, null, dstAddr, size);
            length -= size;
            offset += size;
            dstAddr += size;
        }
    }

从上面来看put(ByteBuffer)操作,如果ByteBuffer为DirectByteBuffer,则利用Unsafe
将源缓冲区position和limit之前的数据拷贝到当前缓冲区。否则拷贝缓冲区字节序列数据到
当前缓冲区。
//写一个int值到缓冲区
 public ByteBuffer putInt(int x) {
     //position向后移动4个字节,获取当前position的内存地址,委托给putInt(long a, int x)
     putInt(ix(nextPutIndex((1 << 2))), x);
     return this;
 }
//将x放到内存地址a上
 private ByteBuffer putInt(long a, int x) {
        //如果系统架构为已知架构,则通过Unsafe将x放到内存地址a上
        if (unaligned) {
            int y = (x);
            unsafe.putInt(a, (nativeByteOrder ? y : Bits.swap(y)));
        } else {
            Bits.putInt(a, x, bigEndian);
        }
        return this;
    }

//Unsafe
 public native void putInt(long l, int i);

来看get(byte )操作
//获取当前索引位置的byte
 public byte get() {
     return ((unsafe.getByte(ix(nextGetIndex()))));
 }
//获取索引i位置的byte
 public byte get(int i) {
     return ((unsafe.getByte(ix(checkIndex(i)))));
 } 
 //读取当前缓冲数据,写到字节数组中
 public ByteBuffer get(byte[] dst, int offset, int length) {
        if ((length << 0) > Bits.JNI_COPY_TO_ARRAY_THRESHOLD) {
            checkBounds(offset, length, dst.length);
	    //在读buffer之前,要调用flip函数,所以position与limit数据,即为缓冲区真实数据
	    //这也是为什么在缓存区读写模式切换时,要调用flip函数的原因
            int pos = position();
            int lim = limit();
            assert (pos <= lim);
            int rem = (pos <= lim ? lim - pos : 0);
            if (length > rem)
	        //如果字节序列长度,大于当前缓冲剩余空间,抛出BufferUnderflowException
                throw new BufferUnderflowException();
            //拷贝当前缓冲数据目的字节数组中
            Bits.copyToArray(ix(pos), dst, arrayBaseOffset,
                                 offset << 0,
                                 length << 0);
            position(pos + length);
        } else {
            super.get(dst, offset, length);
        }
        return this;
    }

//Bit
/**
     * Copy from source address into given destination array.
     *从源地址拷贝length字节到给定的字节数组中
     * @param   srcAddr
     *          source address
     * @param   dst
     *          destination array
     * @param   dstBaseOffset
     *          offset of first element of storage in destination array
     * @param   dstPos
     *          offset within destination array of the first element to write
     * @param   length
     *          number of bytes to copy
     */
    static void copyToArray(long srcAddr, Object dst, long dstBaseOffset, long dstPos,
                            long length)
    {
        long offset = dstBaseOffset + dstPos;
        while (length > 0) {
            long size = (length > UNSAFE_COPY_THRESHOLD) ? UNSAFE_COPY_THRESHOLD : length;
            unsafe.copyMemory(null, srcAddr, dst, offset, size);
            length -= size;
            srcAddr += size;
            offset += size;
        }
    }

从上可以看出get(byte[] dst, int offset, int length)方法,实际上为利用Bit,从当前缓冲地址拷贝length字节到字节数组dst中。
//从缓冲区获取一个int值
public int getInt() {
   //position向后移动4个字节,获取当前position的内存地址,委托给getInt(long a, int x)
    return getInt(ix(nextGetIndex((1 << 2))));
}
private int getInt(long a) {
   //如果系统架构为已知架构,则通过Unsafe从内存地址a上获取一个int值
    if (unaligned) {
        int x = unsafe.getInt(a);
        return (nativeByteOrder ? x : Bits.swap(x));
    }
    return Bits.getInt(a, bigEndian);
}

//Unsafe
public native int getInt(long l);

当然DirectByteBuffer还要其他get和put方法,这里我们就不一一介绍了,大致思路相同。
再看其他一些方法。
//是否为Direct类型缓冲区
public boolean isDirect() {
    return true;
}
//是否只读
public boolean isReadOnly() {
    return false;
}

总结:
在DirectByteBuffer的构造主要是获取系统内存使用是否分页,预留内存,分配内存,设置安全访问对象unsafe的起始位置,设置缓存Buffer的起始位置address,创建buffer的Cleaner。put(ByteBuffer)操作,如果ByteBuffer为DirectByteBuffer,则利用Unsafe的copyMemory方法将源缓冲区position和limit之前的数据拷贝到当前缓冲区。否则拷贝缓冲区字节序列数据到当前缓冲区。get(byte[] dst, int offset, int length)方法,实际上为利用Bit,从当前缓冲地址拷贝length字节到字节数组dst中,实际上是通过Unsafe的copyMemory方法。

附:
//DirectByteBuffer





//DirectBuffer
package sun.nio.ch;
import sun.misc.Cleaner;
public interface DirectBuffer
{
    public abstract long address();
    public abstract Object attachment();
    public abstract Cleaner cleaner();
}

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