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Practical Session 11

Practical Session 11. Multi Client-Server Java NIO. The Server Interface. interface  ServerProtocol : String  processMessage (String  msg );           boolean isEnd (String  msg ); In order to organize the work of the Server, and to allow several protocols, we create an interface:

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Practical Session 11

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  1. Practical Session 11 Multi Client-Server Java NIO

  2. The Server Interface • interface ServerProtocol: • String processMessage(String msg);           • booleanisEnd(String msg); • In order to organize the work of the Server, and to allow several protocols, we create an interface: • processMessage: a function that decides what to do with the content received. • isEnd: returns true if the message equals our ‘exit’ command.

  3. Supporting Multiple Clients • The basic flow of logic in such a server is this: while (true) { accept a connection; create a thread to deal with the client; } • The thread reads from and writes to the client connection as necessary.

  4. ConnectionHandler • In order to allow more than one client to connect to our server, we need to run each connection in its own thread. • ConnectionHandler is a Runnable that handles one connection. • Each client that wishes to connect to our server initiates the connection. • The server accepts the connection from the client. • The socket returned is sent to the ConnectionHandler object. • ConnectionHandler is run as a Thread. • Server goes back to blocking mode, waiting for a new connection.

  5. MultiClient – Server Implementation • ServerProtocol  [Interface] • processMessage • isEnd • EchoProtocol implements ServerProtocol • processMessage: message received is returned • isEnd: returns true if message is ‘bye’ • ConnectionHandler[Runnable] • Receives messages from client [msg = in.readLine()] • Processes message [using process()] using EchoProtocol • If message is ‘bye’, exits thread [protocol.isEnd(msg)] • Else, message is sent back to client [out.println(response)] • Sends returned result from processing to client. • MultipleClientProtocolServer [Runnable] • Our server – runs as a thread • Creates ServerSocket, listens to a port • Runs ConnectionHandler in a thread once accept() returns a socket. http://www.cs.bgu.ac.il/~spl141/PracticalSession10/MultipleClientProtocolServer

  6. Java Non-blocking IO • In our examples, the server gets stuck on • msg = in.readLine() • clientSocket = serverSocket.accept() • out.println(msg) • You cannot do something else while these methods are blocking. (process client messages, handle other clients etc.).

  7. Java Non-blocking IO • Solution? java.nio. • The package is an efficient InputOutput package, which supports Non-blocking IO. • NIO Concepts: • Channels • Buffers • Selectors • Tutorial: http://tutorials.jenkov.com/java-nio/index.html

  8. Channels [our sockets] • An Object you can read from and write to. • Channels can be either blocking (by default) or non-blocking. • SocketChannel: • http://docs.oracle.com/javase/1.4.2/docs/api/java/nio/channels/SocketChannel.html • Same as regular Socket object. • Difference: read(), write() can be non-blocking. • ServerSocketChannel: • http://docs.oracle.com/javase/1.4.2/docs/api/java/nio/channels/ServerSocketChannel.html • accept() returns SocketChannel • Same as regular ServerSocket object. • Difference: accept() can be non-blocking. • Does not block until a client connects. • Checks if a client is trying to connect, if so returns a new socket, otherwise returns null!

  9. Setting up ServerSocketChannel and SocketChannel • ServerSocketChannel : • int port = 9999; • ServerSocketChannelssChannel = ServerSocketChannel.open(); • ssChannel.configureBlocking(false); • ssChannel.socket().bind(new InetSocketAddress(port)); • SocketChannel: • SocketChannelsChannel=SocketChannel.open(); • sChannel.connect(new InetSocketAddress("host/ip", 9999)); • sChannel.configureBlocking(false); http://docs.oracle.com/javase/1.4.2/docs/api/java/net/InetSocketAddress.html

  10. Buffers [our containers] • The objects which hold the data to be sent and data received. • Channels know how to read and write into Buffers, and buffers can read and write into other buffers. • Java NIO comes with the following Buffer types: • ByteBuffer • CharBuffer • DoubleBuffer • FloatBuffer • IntBuffer • LongBuffer • ShortBuffer http://docs.oracle.com/javase/1.4.2/docs/api/java/nio/ByteBuffer.html

  11. Buffer IO Operations • Readingfrom a channel to a buffer: numBytesRead = socketChannel.read(buf); • Contents found in socketChannel are read from their internal container object to our buffer. • Writingfrom a buffer to a channel: numBytesWritten = socketChannel.write(buf); • Contents from our buf object are written to the socketChannel’s internal container to be sent. • If read or write returns -1, it means that the channel is closed. • Read and write operations on Buffers update the position marker accordingly.

  12. Creating Buffers • We'll be using ByteBuffer. • These are buffers that hold bytes. • Creating a new ByteBuffer: [Method I] • final int NUM_OF_BYTES = 1024; • ByteBuffer buffer = ByteBuffer.allocate(NUM_OF_BYTES); • Creating a new ByteBuffer: [Method II] • String message = “Sentence to write into buffer”; • ByteBuffer buffer = ByteBuffer.wrap(message.getBytes(),”UTF-8”);

  13. Buffer Markers • Each buffer has capacity, limit, and position markers. • Capacity: • Being a memory block, a Buffer has a certain fixed size, also called its "capacity". • You can only write capacity bytes, 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: • Writing data to buffer: • 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. • Reading data from buffer: • When you flip a Buffer from writing mode to reading mode, the position is reset to 0. • As you read data from the Buffer you do so from position, and position 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. • The limit is equal to the capacity of the Buffer. • When flipping the Buffer into read mode: • The limit means the limit of how much data you can read from the data. • 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).

  14. Illustration

  15. Usage Example

  16. read/write operations • A read operation readsa specified number of bytes from the current position, and updates the position marker to point to the yet unread bytes. • A write operation writes some bytes from the current position, and then advances the position depending on the number of written bytes. • You can't read or write more than the limit of the buffer. • You can't increase the limit over the capacity. • It can be described as:

  17. Buffer Flipping • 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. • The position marker now marks the reading position, and limit marks how many bytes were written into the buffer - the limit of how many bytes, chars etc. that can be read. • Example: • You create a ByteBuffer. • Write data into the buffer. • Flip() • Send the buffer to the channel.

  18. More ByteBuffer Methods • clear(): • Makes a buffer ready for a new sequence of channel-read or relative put operations. • Sets the limit to the capacity . • Sets the position to zero. • rewind(): • Makes a buffer ready for re-reading the data that it already contains. • Leaves the limit unchanged. • Sets the position to zero.

  19. StringMessageTokenizerInterface • void addBytes(ByteBuffer bytes); • Receives a Buffer of bytes containing data to be converted to chars. • booleanhasMessage(); • Is there a complete message ready? • String nextMessage(); • Get the next complete message if it exists, advancing the tokenizer to the next message.

  20. FixedSeparatorMessageTokenizer • FixedSeparatorMessageTokenizer(String separator, Charset charset) • The constructor. • Between two messages in the buffer we have a separator. • Messages are encoded [chars to bytes] and decoded [bytes to chars] using the given charset [ASCII, UTF-8] • public synchronized void addBytes(ByteBuffer bytes): • Array of bytes received is converted to string and concatenated to the ones before it. • public synchronized booleanhasMessage(): • Checks if the buffer has a complete message, if so true, otherwise false. [done by checking if the separator exists in the string array] • public synchronized String nextMessage() • Returns the next complete message in the buffer.

  21. NIO Echo Client • http://www.cs.bgu.ac.il/~spl141/PracticalSession10/NIOEchoClient

  22. C++ Echo Client • Connect a socket to a host and port: tcp::socket socket; tcp::endpoint endpoint(boost::asio::ip::address::from_string(hostIPValue), portValue); boost::system::error_code error; socket.connect(endpoint, error); • Read from socket: buffer(startingPointPointer, sizeToReadInBytes, exception) //exception is optional //tmp holds the number of bytes read so far; bytes: an array of chars to read the received bytes from socket.read_some(boost::asio::buffer(bytes+tmp, bytesToRead-tmp), error) • Write to socket: socket.write_some(boost::asio::buffer(bytes + tmp, bytesToWrite - tmp), error) • Example: • 05_Boost_Echo_Client

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