zoukankan      html  css  js  c++  java
  • Java NIO Buffer


    Java Nio 

    1Java NIO Tutorial
    2Java NIO Overview
    3Java NIO Channel
    4Java NIO Buffer
    5Java NIO Scatter / Gather
    6Java NIO Channel to Channel Transfers
    7Java NIO Selector
    8Java NIO FileChannel
    9Java NIO SocketChannel
    10Java NIO ServerSocketChannel
    11Java NIO DatagramChannel
    12Java NIO Pipe
    13Java NIO vs. IO

    Java NIO Buffer

     
    By Jakob Jenkov
     Connect with me: 
    Rate article:
    Share article:

    Java NIO Buffers are used when interacting with NIO Channels. As you know, data is read from channels into buffers, and written from buffers into channels.

    A buffer is essentially a block of memory into which you can write data, which you can then later read again. This memory block is wrapped in a NIO Buffer object, which provides a set of methods that makes it easier to work with the memory block.

    Basic Buffer Usage

    Using a Buffer to read and write data typically follows this little 4-step process:

    1. Write data into the Buffer
    2. Call buffer.flip()
    3. Read data out of the Buffer
    4. Call buffer.clear() or buffer.compact()

    When you write data into a buffer, the buffer keeps track of how much data you have written. Once you need to read the data, you need to switch the buffer from writing mode into reading mode using the flip() method call. In reading mode the buffer lets you read all the data written into the buffer.

    Once you have read all the data, you need to clear the buffer, to make it ready for writing again. You can do this in two ways: By calling clear() or by calling compact(). The clear() method clears the whole buffer. The compact()method only clears the data which you have already read. Any unread data is moved to the beginning of the buffer, and data will now be written into the buffer after the unread data.

    Here is a simple Buffer usage example, with the write, flip, read and clear operations maked in bold:

    RandomAccessFile aFile = new RandomAccessFile("data/nio-data.txt", "rw");
    FileChannel inChannel = aFile.getChannel();
    
    //create buffer with capacity of 48 bytes
    ByteBuffer buf = ByteBuffer.allocate(48);
    
    int bytesRead = inChannel.read(buf); //read into buffer.
    while (bytesRead != -1) {
    
      buf.flip();  //make buffer ready for read
    
      while(buf.hasRemaining()){
          System.out.print((char) buf.get()); // read 1 byte at a time
      }
    
      buf.clear(); //make buffer ready for writing
      bytesRead = inChannel.read(buf);
    }
    aFile.close();
    

    Buffer Capacity, Position and Limit

    A buffer is essentially a block of memory into which you can write data, which you can then later read again. This memory block is wrapped in a NIO Buffer object, which provides a set of methods that makes it easier to work with the memory block.

    Buffer has three properties you need to be familiar with, in order to understand how a Buffer works. These are:

    • capacity
    • position
    • limit

    The meaning of position and limit depends on whether the Buffer is in read or write mode. Capacity always means the same, no matter the buffer mode.

    Here is an illustration of capacity, position and limit in write and read modes. The explanation follows in the sections after the illustration.

    Java NIO: Buffer capacity, position and limit in write and read mode.
    Buffer capacity, position and limit in write and read mode.

    Capacity

    Being a memory block, a Buffer has a certain fixed size, also called its "capacity". You can only write capacitybytes, longs, chars etc. into the Buffer. Once the Buffer is full, you need to empty it (read the data, or clear it) before you can write more data into it.

    Position

    When you write data into the Buffer, you do so at a certain position. Initially the position is 0. When a byte, long etc. has been written into the Buffer the position is advanced to point to the next cell in the buffer to insert data into. Position can maximally become capacity - 1.

    When you read data from a Buffer you also do so from a given position. When you flip a Buffer from writing mode to reading mode, the position is reset back to 0. As you read data from the Buffer you do so from position, andposition is advanced to next position to read.

    Limit

    In write mode the limit of a Buffer is the limit of how much data you can write into the buffer. In write mode the limit is equal to the capacity of the Buffer.

    When flipping the Buffer into read mode, limit means the limit of how much data you can read from the data. Therefore, when flipping a Buffer into read mode, limit is set to write position of the write mode. In other words, you can read as many bytes as were written (limit is set to the number of bytes written, which is marked by position).

    Buffer Types

    Java NIO comes with the following Buffer types:

    • ByteBuffer
    • MappedByteBuffer
    • CharBuffer
    • DoubleBuffer
    • FloatBuffer
    • IntBuffer
    • LongBuffer
    • ShortBuffer

    As you can see, these Buffer types represent different data types. In other words, they let you work with the bytes in the buffer as char, short, int, long, float or double instead.

    The MappedByteBuffer is a bit special, and will be covered in its own text.

    Allocating a Buffer

    To obtain a Buffer object you must first allocate it. Every Buffer class has an allocate() method that does this. Here is an example showing the allocation of a ByteBuffer, with a capacity of 48 bytes:

    ByteBuffer buf = ByteBuffer.allocate(48);
    

    Here is an example allocating a CharBuffer with space for 1024 characters:

    CharBuffer buf = CharBuffer.allocate(1024);
    

    Writing Data to a Buffer

    You can write data into a Buffer in two ways:

    1. Write data from a Channel into a Buffer
    2. Write data into the Buffer yourself, via the buffer's put() methods.

    Here is an example showing how a Channel can write data into a Buffer:

    int bytesRead = inChannel.read(buf); //read into buffer.
    

    Here is an example that writes data into a Buffer via the put() method:

    buf.put(127);    
    

    There are many other versions of the put() method, allowing you to write data into the Buffer in many different ways. For instance, writing at specific positions, or writing an array of bytes into the buffer. See the JavaDoc for the concrete buffer implementation for more details.

    flip()

    The flip() method switches a Buffer from writing mode to reading mode. Calling flip() sets the position back to 0, and sets the limit to where position just was.

    In other words, position now marks the reading position, and limit marks how many bytes, chars etc. were written into the buffer - the limit of how many bytes, chars etc. that can be read.

    Reading Data from a Buffer

    There are two ways you can read data from a Buffer.

    1. Read data from the buffer into a channel.
    2. Read data from the buffer yourself, using one of the get() methods.

    Here is an example of how you can read data from a buffer into a channel:

    //read from buffer into channel.
    int bytesWritten = inChannel.write(buf);
    

    Here is an example that reads data from a Buffer using the get() method:

    byte aByte = buf.get();    
    

    There are many other versions of the get() method, allowing you to read data from the Buffer in many different ways. For instance, reading at specific positions, or reading an array of bytes from the buffer. See the JavaDoc for the concrete buffer implementation for more details.

    rewind()

    The Buffer.rewind() sets the position back to 0, so you can reread all the data in the buffer. The limitremains untouched, thus still marking how many elements (bytes, chars etc.) that can be read from the Buffer.

    clear() and compact()

    Once you are done reading data out of the Buffer you have to make the Buffer ready for writing again. You can do so either by calling clear() or by calling compact().

    If you call clear() the position is set back to 0 and the limit to capacity. In other words, the Buffer is cleared. The data in the Buffer is not cleared. Only the markers telling where you can write data into the Buffer are.

    If there is any unread data in the Buffer when you call clear() that data will be "forgotten", meaning you no longer have any markers telling what data has been read, and what has not been read.

    If there is still unread data in the Buffer, and you want to read it later, but you need to do some writing first, callcompact() instead of clear().

    compact() copies all unread data to the beginning of the Buffer. Then it sets position to right after the last unread element. The limit property is still set to capacity, just like clear() does. Now the Buffer is ready for writing, but you will not overwrite the unread data.

    mark() and reset()

    You can mark a given position in a Buffer by calling the Buffer.mark() method. You can then later reset the position back to the marked position by calling the Buffer.reset() method. Here is an example:

    buffer.mark();
    
    //call buffer.get() a couple of times, e.g. during parsing.
    
    buffer.reset();  //set position back to mark.    
    

    equals() and compareTo()

    It is possible to compare two buffers using equals() and compareTo().

    equals()

    Two buffers are equal if:

    1. They are of the same type (byte, char, int etc.)
    2. They have the same amount of remaining bytes, chars etc. in the buffer.
    3. All remaining bytes, chars etc. are equal.

    As you can see, equals only compares part of the Buffer, not every single element inside it. In fact, it just compares the remaining elements in the Buffer.

    compareTo()

    The compareTo() method compares the remaining elements (bytes, chars etc.) of the two buffers, for use in e.g. sorting routines. A buffer is considered "smaller" than another buffer if:

    1. The first element which is equal to the corresponding element in the other buffer, is smaller than that in the other buffer.
    2. All elements are equal, but the first buffer runs out of elements before the second buffer does (it has fewer elements).







  • 相关阅读:
    Pyhton学习——Day60
    Pyhton学习——Day58
    Python——微信数据分析
    C/C++文件指针偏移
    I/O流+统计文件词频
    vector概念
    new/delete工作机制
    Singleton单例类模式
    对象数组
    特殊成员函数
  • 原文地址:https://www.cnblogs.com/mengfanrong/p/5268462.html
Copyright © 2011-2022 走看看