/*
* Copyright (C) 2012 The Android Open Source Project
*
* Licensed 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 android.bluetooth;
import android.net.LocalSocket;
import android.os.ParcelFileDescriptor;
import android.os.ParcelUuid;
import android.os.RemoteException;
import android.util.Log;
import java.io.Closeable;
import java.io.FileDescriptor;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.util.Arrays;
import java.util.Locale;
import java.util.UUID;
/**
* A connected or connecting Bluetooth socket.
*
* The interface for Bluetooth Sockets is similar to that of TCP sockets:
* {@link java.net.Socket} and {@link java.net.ServerSocket}. On the server
* side, use a {@link BluetoothServerSocket} to create a listening server
* socket. When a connection is accepted by the {@link BluetoothServerSocket},
* it will return a new {@link BluetoothSocket} to manage the connection.
* On the client side, use a single {@link BluetoothSocket} to both initiate
* an outgoing connection and to manage the connection.
*
*
The most common type of Bluetooth socket is RFCOMM, which is the type
* supported by the Android APIs. RFCOMM is a connection-oriented, streaming
* transport over Bluetooth. It is also known as the Serial Port Profile (SPP).
*
*
To create a {@link BluetoothSocket} for connecting to a known device, use
* {@link BluetoothDevice#createRfcommSocketToServiceRecord
* BluetoothDevice.createRfcommSocketToServiceRecord()}.
* Then call {@link #connect()} to attempt a connection to the remote device.
* This call will block until a connection is established or the connection
* fails.
*
*
To create a {@link BluetoothSocket} as a server (or "host"), see the
* {@link BluetoothServerSocket} documentation.
*
*
Once the socket is connected, whether initiated as a client or accepted
* as a server, open the IO streams by calling {@link #getInputStream} and
* {@link #getOutputStream} in order to retrieve {@link java.io.InputStream}
* and {@link java.io.OutputStream} objects, respectively, which are
* automatically connected to the socket.
*
*
{@link BluetoothSocket} is thread
* safe. In particular, {@link #close} will always immediately abort ongoing
* operations and close the socket.
*
*
Note:
* Requires the {@link android.Manifest.permission#BLUETOOTH} permission.
*
*
*
Developer Guides
*
For more information about using Bluetooth, read the
* Bluetooth developer guide.
*
The input stream will be returned even if the socket is not yet
* connected, but operations on that stream will throw IOException until
* the associated socket is connected.
*
* @return InputStream
*/
public InputStream getInputStream() throws IOException {
return mInputStream;
}
/**
* Get the output stream associated with this socket.
*
The output stream will be returned even if the socket is not yet
* connected, but operations on that stream will throw IOException until
* the associated socket is connected.
*
* @return OutputStream
*/
public OutputStream getOutputStream() throws IOException {
return mOutputStream;
}
/**
* Get the connection status of this socket, ie, whether there is an active connection with
* remote device.
*
* @return true if connected false if not connected
*/
public boolean isConnected() {
return mSocketState == SocketState.CONNECTED;
}
/*package*/ void setServiceName(String name) {
mServiceName = name;
}
/**
* Attempt to connect to a remote device.
*
This method will block until a connection is made or the connection
* fails. If this method returns without an exception then this socket
* is now connected.
*
Creating new connections to
* remote Bluetooth devices should not be attempted while device discovery
* is in progress. Device discovery is a heavyweight procedure on the
* Bluetooth adapter and will significantly slow a device connection.
* Use {@link BluetoothAdapter#cancelDiscovery()} to cancel an ongoing
* discovery. Discovery is not managed by the Activity,
* but is run as a system service, so an application should always call
* {@link BluetoothAdapter#cancelDiscovery()} even if it
* did not directly request a discovery, just to be sure.
*
{@link #close} can be used to abort this call from another thread.
*
* @throws IOException on error, for example connection failure
*/
public void connect() throws IOException {
if (mDevice == null) throw new IOException("Connect is called on null device");
try {
if (mSocketState == SocketState.CLOSED) throw new IOException("socket closed");
IBluetooth bluetoothProxy =
BluetoothAdapter.getDefaultAdapter().getBluetoothService(null);
if (bluetoothProxy == null) throw new IOException("Bluetooth is off");
mPfd = bluetoothProxy.getSocketManager().connectSocket(mDevice, mType,
mUuid, mPort, getSecurityFlags());
synchronized (this) {
if (DBG) Log.d(TAG, "connect(), SocketState: " + mSocketState + ", mPfd: " + mPfd);
if (mSocketState == SocketState.CLOSED) throw new IOException("socket closed");
if (mPfd == null) throw new IOException("bt socket connect failed");
FileDescriptor fd = mPfd.getFileDescriptor();
mSocket = LocalSocket.createConnectedLocalSocket(fd);
mSocketIS = mSocket.getInputStream();
mSocketOS = mSocket.getOutputStream();
}
int channel = readInt(mSocketIS);
if (channel <= 0) {
throw new IOException("bt socket connect failed");
}
mPort = channel;
waitSocketSignal(mSocketIS);
synchronized (this) {
if (mSocketState == SocketState.CLOSED) {
throw new IOException("bt socket closed");
}
mSocketState = SocketState.CONNECTED;
}
} catch (RemoteException e) {
Log.e(TAG, Log.getStackTraceString(new Throwable()));
throw new IOException("unable to send RPC: " + e.getMessage());
}
}
/**
* Currently returns unix errno instead of throwing IOException,
* so that BluetoothAdapter can check the error code for EADDRINUSE
*/
/*package*/ int bindListen() {
int ret;
if (mSocketState == SocketState.CLOSED) return EBADFD;
IBluetooth bluetoothProxy = BluetoothAdapter.getDefaultAdapter().getBluetoothService(null);
if (bluetoothProxy == null) {
Log.e(TAG, "bindListen fail, reason: bluetooth is off");
return -1;
}
try {
if (DBG) Log.d(TAG, "bindListen(): mPort=" + mPort + ", mType=" + mType);
mPfd = bluetoothProxy.getSocketManager().createSocketChannel(mType, mServiceName,
mUuid, mPort, getSecurityFlags());
} catch (RemoteException e) {
Log.e(TAG, Log.getStackTraceString(new Throwable()));
return -1;
}
// read out port number
try {
synchronized (this) {
if (DBG) {
Log.d(TAG, "bindListen(), SocketState: " + mSocketState + ", mPfd: " + mPfd);
}
if (mSocketState != SocketState.INIT) return EBADFD;
if (mPfd == null) return -1;
FileDescriptor fd = mPfd.getFileDescriptor();
if (fd == null) {
Log.e(TAG, "bindListen(), null file descriptor");
return -1;
}
if (DBG) Log.d(TAG, "bindListen(), Create LocalSocket");
mSocket = LocalSocket.createConnectedLocalSocket(fd);
if (DBG) Log.d(TAG, "bindListen(), new LocalSocket.getInputStream()");
mSocketIS = mSocket.getInputStream();
mSocketOS = mSocket.getOutputStream();
}
if (DBG) Log.d(TAG, "bindListen(), readInt mSocketIS: " + mSocketIS);
int channel = readInt(mSocketIS);
synchronized (this) {
if (mSocketState == SocketState.INIT) {
mSocketState = SocketState.LISTENING;
}
}
if (DBG) Log.d(TAG, "bindListen(): channel=" + channel + ", mPort=" + mPort);
if (mPort <= -1) {
mPort = channel;
} // else ASSERT(mPort == channel)
ret = 0;
} catch (IOException e) {
if (mPfd != null) {
try {
mPfd.close();
} catch (IOException e1) {
Log.e(TAG, "bindListen, close mPfd: " + e1);
}
mPfd = null;
}
Log.e(TAG, "bindListen, fail to get port number, exception: " + e);
return -1;
}
return ret;
}
/*package*/ BluetoothSocket accept(int timeout) throws IOException {
BluetoothSocket acceptedSocket;
if (mSocketState != SocketState.LISTENING) {
throw new IOException("bt socket is not in listen state");
}
if (timeout > 0) {
Log.d(TAG, "accept() set timeout (ms):" + timeout);
mSocket.setSoTimeout(timeout);
}
String RemoteAddr = waitSocketSignal(mSocketIS);
if (timeout > 0) {
mSocket.setSoTimeout(0);
}
synchronized (this) {
if (mSocketState != SocketState.LISTENING) {
throw new IOException("bt socket is not in listen state");
}
acceptedSocket = acceptSocket(RemoteAddr);
//quick drop the reference of the file handle
}
return acceptedSocket;
}
/*package*/ int available() throws IOException {
if (VDBG) Log.d(TAG, "available: " + mSocketIS);
return mSocketIS.available();
}
/**
* Wait until the data in sending queue is emptied. A polling version
* for flush implementation. Used to ensure the writing data afterwards will
* be packed in new RFCOMM frame.
*
* @throws IOException if an i/o error occurs.
*/
/*package*/ void flush() throws IOException {
if (mSocketOS == null) throw new IOException("flush is called on null OutputStream");
if (VDBG) Log.d(TAG, "flush: " + mSocketOS);
mSocketOS.flush();
}
/*package*/ int read(byte[] b, int offset, int length) throws IOException {
int ret = 0;
if (VDBG) Log.d(TAG, "read in: " + mSocketIS + " len: " + length);
if ((mType == TYPE_L2CAP) || (mType == TYPE_L2CAP_LE)) {
int bytesToRead = length;
if (VDBG) {
Log.v(TAG, "l2cap: read(): offset: " + offset + " length:" + length
+ "mL2capBuffer= " + mL2capBuffer);
}
if (mL2capBuffer == null) {
createL2capRxBuffer();
}
if (mL2capBuffer.remaining() == 0) {
if (VDBG) Log.v(TAG, "l2cap buffer empty, refilling...");
if (fillL2capRxBuffer() == -1) {
return -1;
}
}
if (bytesToRead > mL2capBuffer.remaining()) {
bytesToRead = mL2capBuffer.remaining();
}
if (VDBG) {
Log.v(TAG, "get(): offset: " + offset
+ " bytesToRead: " + bytesToRead);
}
mL2capBuffer.get(b, offset, bytesToRead);
ret = bytesToRead;
} else {
if (VDBG) Log.v(TAG, "default: read(): offset: " + offset + " length:" + length);
ret = mSocketIS.read(b, offset, length);
}
if (ret < 0) {
throw new IOException("bt socket closed, read return: " + ret);
}
if (VDBG) Log.d(TAG, "read out: " + mSocketIS + " ret: " + ret);
return ret;
}
/*package*/ int write(byte[] b, int offset, int length) throws IOException {
//TODO: Since bindings can exist between the SDU size and the
// protocol, we might need to throw an exception instead of just
// splitting the write into multiple smaller writes.
// Rfcomm uses dynamic allocation, and should not have any bindings
// to the actual message length.
if (VDBG) Log.d(TAG, "write: " + mSocketOS + " length: " + length);
if ((mType == TYPE_L2CAP) || (mType == TYPE_L2CAP_LE)) {
if (length <= mMaxTxPacketSize) {
mSocketOS.write(b, offset, length);
} else {
if (DBG) {
Log.w(TAG, "WARNING: Write buffer larger than L2CAP packet size!\n"
+ "Packet will be divided into SDU packets of size "
+ mMaxTxPacketSize);
}
int tmpOffset = offset;
int bytesToWrite = length;
while (bytesToWrite > 0) {
int tmpLength = (bytesToWrite > mMaxTxPacketSize)
? mMaxTxPacketSize
: bytesToWrite;
mSocketOS.write(b, tmpOffset, tmpLength);
tmpOffset += tmpLength;
bytesToWrite -= tmpLength;
}
}
} else {
mSocketOS.write(b, offset, length);
}
// There is no good way to confirm since the entire process is asynchronous anyway
if (VDBG) Log.d(TAG, "write out: " + mSocketOS + " length: " + length);
return length;
}
@Override
public void close() throws IOException {
Log.d(TAG, "close() this: " + this + ", channel: " + mPort + ", mSocketIS: " + mSocketIS
+ ", mSocketOS: " + mSocketOS + "mSocket: " + mSocket + ", mSocketState: "
+ mSocketState);
if (mSocketState == SocketState.CLOSED) {
return;
} else {
synchronized (this) {
if (mSocketState == SocketState.CLOSED) {
return;
}
mSocketState = SocketState.CLOSED;
if (mSocket != null) {
if (DBG) Log.d(TAG, "Closing mSocket: " + mSocket);
mSocket.shutdownInput();
mSocket.shutdownOutput();
mSocket.close();
mSocket = null;
}
if (mPfd != null) {
mPfd.close();
mPfd = null;
}
}
}
}
/*package */ void removeChannel() {
}
/*package */ int getPort() {
return mPort;
}
/**
* Get the maximum supported Transmit packet size for the underlying transport.
* Use this to optimize the writes done to the output socket, to avoid sending
* half full packets.
*
* @return the maximum supported Transmit packet size for the underlying transport.
*/
public int getMaxTransmitPacketSize() {
return mMaxTxPacketSize;
}
/**
* Get the maximum supported Receive packet size for the underlying transport.
* Use this to optimize the reads done on the input stream, as any call to read
* will return a maximum of this amount of bytes - or for some transports a
* multiple of this value.
*
* @return the maximum supported Receive packet size for the underlying transport.
*/
public int getMaxReceivePacketSize() {
return mMaxRxPacketSize;
}
/**
* Get the type of the underlying connection.
*
* @return one of {@link #TYPE_RFCOMM}, {@link #TYPE_SCO} or {@link #TYPE_L2CAP}
*/
public int getConnectionType() {
return mType;
}
/**
* Change if a SDP entry should be automatically created.
* Must be called before calling .bind, for the call to have any effect.
*
* @param excludeSdp
TRUE - do not auto generate SDP record. FALSE - default - auto
* generate SPP SDP record.
* @hide
*/
public void setExcludeSdp(boolean excludeSdp) {
mExcludeSdp = excludeSdp;
}
/**
* Set the LE Transmit Data Length to be the maximum that the BT Controller is capable of. This
* parameter is used by the BT Controller to set the maximum transmission packet size on this
* connection. This function is currently used for testing only.
* @hide
*/
public void requestMaximumTxDataLength() throws IOException {
if (mDevice == null) {
throw new IOException("requestMaximumTxDataLength is called on null device");
}
try {
if (mSocketState == SocketState.CLOSED) {
throw new IOException("socket closed");
}
IBluetooth bluetoothProxy =
BluetoothAdapter.getDefaultAdapter().getBluetoothService(null);
if (bluetoothProxy == null) {
throw new IOException("Bluetooth is off");
}
if (DBG) Log.d(TAG, "requestMaximumTxDataLength");
bluetoothProxy.getSocketManager().requestMaximumTxDataLength(mDevice);
} catch (RemoteException e) {
Log.e(TAG, Log.getStackTraceString(new Throwable()));
throw new IOException("unable to send RPC: " + e.getMessage());
}
}
private String convertAddr(final byte[] addr) {
return String.format(Locale.US, "%02X:%02X:%02X:%02X:%02X:%02X",
addr[0], addr[1], addr[2], addr[3], addr[4], addr[5]);
}
private String waitSocketSignal(InputStream is) throws IOException {
byte[] sig = new byte[SOCK_SIGNAL_SIZE];
int ret = readAll(is, sig);
if (VDBG) {
Log.d(TAG, "waitSocketSignal read " + SOCK_SIGNAL_SIZE + " bytes signal ret: " + ret);
}
ByteBuffer bb = ByteBuffer.wrap(sig);
/* the struct in native is decorated with __attribute__((packed)), hence this is possible */
bb.order(ByteOrder.nativeOrder());
int size = bb.getShort();
if (size != SOCK_SIGNAL_SIZE) {
throw new IOException("Connection failure, wrong signal size: " + size);
}
byte[] addr = new byte[6];
bb.get(addr);
int channel = bb.getInt();
int status = bb.getInt();
mMaxTxPacketSize = (bb.getShort() & 0xffff); // Convert to unsigned value
mMaxRxPacketSize = (bb.getShort() & 0xffff); // Convert to unsigned value
String RemoteAddr = convertAddr(addr);
if (VDBG) {
Log.d(TAG, "waitSocketSignal: sig size: " + size + ", remote addr: "
+ RemoteAddr + ", channel: " + channel + ", status: " + status
+ " MaxRxPktSize: " + mMaxRxPacketSize + " MaxTxPktSize: " + mMaxTxPacketSize);
}
if (status != 0) {
throw new IOException("Connection failure, status: " + status);
}
return RemoteAddr;
}
private void createL2capRxBuffer() {
if ((mType == TYPE_L2CAP) || (mType == TYPE_L2CAP_LE)) {
// Allocate the buffer to use for reads.
if (VDBG) Log.v(TAG, " Creating mL2capBuffer: mMaxPacketSize: " + mMaxRxPacketSize);
mL2capBuffer = ByteBuffer.wrap(new byte[mMaxRxPacketSize]);
if (VDBG) Log.v(TAG, "mL2capBuffer.remaining()" + mL2capBuffer.remaining());
mL2capBuffer.limit(0); // Ensure we do a real read at the first read-request
if (VDBG) {
Log.v(TAG, "mL2capBuffer.remaining() after limit(0):" + mL2capBuffer.remaining());
}
}
}
private int readAll(InputStream is, byte[] b) throws IOException {
int left = b.length;
while (left > 0) {
int ret = is.read(b, b.length - left, left);
if (ret <= 0) {
throw new IOException("read failed, socket might closed or timeout, read ret: "
+ ret);
}
left -= ret;
if (left != 0) {
Log.w(TAG, "readAll() looping, read partial size: " + (b.length - left)
+ ", expect size: " + b.length);
}
}
return b.length;
}
private int readInt(InputStream is) throws IOException {
byte[] ibytes = new byte[4];
int ret = readAll(is, ibytes);
if (VDBG) Log.d(TAG, "inputStream.read ret: " + ret);
ByteBuffer bb = ByteBuffer.wrap(ibytes);
bb.order(ByteOrder.nativeOrder());
return bb.getInt();
}
private int fillL2capRxBuffer() throws IOException {
mL2capBuffer.rewind();
int ret = mSocketIS.read(mL2capBuffer.array());
if (ret == -1) {
// reached end of stream - return -1
mL2capBuffer.limit(0);
return -1;
}
mL2capBuffer.limit(ret);
return ret;
}
}