Пример #1
0
 def processResponse(self, ident, code, data):
     'internal to the i/o thread w/ recv ctrl; processes incoming response'
     chan = self.qmap.pop(ident, None)
     if not chan: return
     buf = JdwpBuffer()
     buf.config(*self.sizes)
     buf.prepareUnpack(data)
     return chan.put((code, buf))
Пример #2
0
 def processRequest(self, ident, code, data):
     'internal to the i/o thread w/ recv ctrl; processes incoming request'
     chan = self.rmap.get(code)
     if not chan: return #TODO
     buf = JdwpBuffer()
     buf.config(*self.sizes)
     buf.prepareUnpack(data)
     return chan.put((ident, buf))
Пример #3
0
 def __init__(self, read, write):
     Thread.__init__(self)
     self.xmitbuf = JdwpBuffer()
     self.recvbuf = JdwpBuffer()
     self._read = read
     self.write = write
     self.initialized = False
     self.next_id = 3
     self.bindqueue = Queue()
     self.qmap = {}
     self.rmap = {}
     self.xmitlock = Lock()
Пример #4
0
 def __init__(self, read, write):
     Thread.__init__(self)
     self.xmitbuf = JdwpBuffer()
     self.recvbuf = JdwpBuffer()
     self._read = read
     self.write = write
     self.initialized = False
     self.next_id = 3
     self.bindqueue = Queue()
     self.qmap = {}
     self.rmap = {}
     self.xmitlock = Lock()
Пример #5
0
 def __init__(self, read, write):
     Thread.__init__(self)
     self.xmitbuf = JdwpBuffer()  #具体实现在jdwp文件中,用C语言实现,这块需要了解C语言嵌入python语言的知识
     self.recvbuf = JdwpBuffer()
     self._read = read
     self.write = write
     self.initialized = False
     self.next_id = 3  #下一个请求id,『可能每次请求都是有序号的』
     self.bindqueue = Queue()  #定义一个先进先出的队列
     self.qmap = {}   #初始化一个空的字典
     self.rmap = {}   #初始化一个空的字典
     self.xmitlock = Lock()  #是一个互斥锁
Пример #6
0
 def processResponse(self, ident, code, data):
     'internal to the i/o thread w/ recv ctrl; processes incoming response'
     chan = self.qmap.pop(ident, None)
     if not chan: return
     buf = JdwpBuffer()
     buf.config(*self.sizes)
     buf.prepareUnpack(data)
     return chan.put((code, buf))
Пример #7
0
 def processRequest(self, ident, code, data):
     'internal to the i/o thread w/ recv ctrl; processes incoming request'
     chan = self.rmap.get(code)
     if not chan: return  #TODO
     buf = JdwpBuffer()
     buf.config(*self.sizes)
     buf.prepareUnpack(data)
     return chan.put((ident, buf))
Пример #8
0
 def processResponse(self, ident, code, data):
     'internal to the i/o thread w/ recv ctrl; processes incoming response'
     log.debug("study", "In Connection.processResponse ident=" + str(ident) + "\t code=" + str(code) + "\t data=")
     chan = self.qmap.pop(ident, None) #从字典中读取,并删除该数据
     if not chan: return
     buf = JdwpBuffer()
     buf.config(*self.sizes)
     buf.prepareUnpack(data)
     return chan.put((code, buf))
Пример #9
0
 def processRequest(self, ident, code, data):
     'internal to the i/o thread w/ recv ctrl; processes incoming request'
     log.debug("study", "In Connection.processRequest ident=" + str(ident) + "\t code=" + str(code) + "\t data=")
     chan = self.rmap.get(code)  #所有中断都由该chan队列处理,每次只是从rmap读出内容,而没有将rmap对应的chan清除
     if not chan: return #TODO
     buf = JdwpBuffer()
     buf.config(*self.sizes)
     buf.prepareUnpack(data)
     return chan.put((ident, buf)) #将解析后的数据压入队列中
Пример #10
0
 def buffer(self):
     'returns a JdwpBuffer configured for this connection'
     buf = JdwpBuffer()
     buf.config(*self.sizes)
     return buf
Пример #11
0
class Connection(Thread):
    '''
    The JDWP Connection is a thread which abstracts the asynchronous JDWP protocol
    into a more synchronous one.  The thread will listen for packets using the
    supplied read function, and transmit them using the write function.  

    Requests are sent by the processor using the calling thread, with a mutex 
    used to protect the write function from concurrent access.  The requesting
    thread is then blocked waiting on a response from the processor thread.

    The Connectionor will repeatedly use the read function to receive packets, which
    will be dispatched based on whether they are responses to a previous request,
    or events.  Responses to requests will cause the requesting thread to be
    unblocked, thus simulating a synchronous request.
    '''
    def __init__(self, read, write):
        Thread.__init__(self)
        self.xmitbuf = JdwpBuffer()
        self.recvbuf = JdwpBuffer()
        self._read = read
        self.write = write
        self.initialized = False
        self.next_id = 3
        self.bindqueue = Queue()
        self.qmap = {}
        self.rmap = {}
        self.xmitlock = Lock()

    def read(self, sz):
        'read size bytes'
        if sz == 0: return ''
        pkt = self._read(sz)
        if not len(pkt): raise EOF()
        return pkt

    ###################################################### INITIALIZATION STEPS

    def writeIdSzReq(self):
        'write an id size request'
        return self.write(IDSZ_REQ)

    def readIdSzRes(self):
        'read an id size response'
        head = self.readHeader()
        if head[0] != 20:
            raise ProtocolError('expected size of an idsize response')
        if head[2] != 0x80:
            raise ProtocolError(
                'expected first server message to be a response')
        if head[1] != 1:
            raise ProtocolError('expected first server message to be 1')

        sizes = self.recvbuf.unpack('iiiii', self.read(20))
        self.sizes = sizes
        self.recvbuf.config(*sizes)
        self.xmitbuf.config(*sizes)
        return None

    def readHandshake(self):
        'read the jdwp handshake'
        data = self.read(len(HANDSHAKE_MSG))
        if data != HANDSHAKE_MSG:
            raise HandshakeError()

    def writeHandshake(self):
        'write the jdwp handshake'
        return self.write(HANDSHAKE_MSG)

    ############################################### READING / PROCESSING PACKETS

    def readHeader(self):
        'reads a header and returns [size, id, flags, event]'
        head = self.read(11)
        data = self.recvbuf.unpack(HEADER_FORMAT, head)
        data[0] -= 11
        return data

    def process(self):
        'invoked repeatedly by the processing thread'

        size, ident, flags, code = self.readHeader()  #TODO: HANDLE CLOSE
        data = self.read(size)  #TODO: HANDLE CLOSE
        try:  # We process binds after receiving messages to prevent a race
            while True:
                self.processBind(*self.bindqueue.get(False))
        except EmptyQueue:
            pass

        #TODO: update binds with all from bindqueue

        if flags == 0x80:
            self.processResponse(ident, code, data)
        else:
            self.processRequest(ident, code, data)

    def processBind(self, qr, ident, chan):
        'internal to i/o thread; performs a query or request bind'
        if qr == 'q':
            self.qmap[ident] = chan
        elif qr == 'r':
            self.rmap[ident] = chan

    def processRequest(self, ident, code, data):
        'internal to the i/o thread w/ recv ctrl; processes incoming request'
        chan = self.rmap.get(code)
        if not chan: return  #TODO
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        buf.prepareUnpack(data)
        return chan.put((ident, buf))

    def processResponse(self, ident, code, data):
        'internal to the i/o thread w/ recv ctrl; processes incoming response'
        chan = self.qmap.pop(ident, None)
        if not chan: return
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        buf.prepareUnpack(data)
        return chan.put((code, buf))

    def hook(self, code, chan):
        '''
        when code requests are received, they will be put in chan for
        processing
        '''

        with self.xmitlock:
            self.bindqueue.put(('r', code, chan))

    ####################################################### TRANSMITTING PACKETS

    def acquireIdent(self):
        'used internally by the processor; must have xmit control'
        ident = self.next_id
        self.next_id += 2
        return ident

    def writeContent(self, ident, flags, code, body):
        'used internally by the processor; must have xmit control'

        size = len(body) + 11
        self.xmitbuf.preparePack(11)
        data = self.xmitbuf.pack(HEADER_FORMAT, size, ident, flags, code)
        self.write(data)
        return self.write(body)

    def request(self, code, data='', timeout=None):
        'send a request, then waits for a response; returns response'
        queue = Queue()

        with self.xmitlock:
            ident = self.acquireIdent()
            self.bindqueue.put(('q', ident, queue))
            self.writeContent(ident, 0x0, code, data)

        try:
            return queue.get(1, timeout)
        except EmptyQueue:
            return None

    def buffer(self):
        'returns a JdwpBuffer configured for this connection'
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        return buf

    ################################################################# THREAD API

    def start(self):
        'performs handshaking and solicits configuration information'
        self.daemon = True

        if not self.initialized:
            self.writeHandshake()
            self.readHandshake()
            self.writeIdSzReq()
            self.readIdSzRes()
            self.initialized = True
            Thread.start(self)
        return None

    def run(self):
        'runs forever; overrides the default Thread.run()'
        try:
            while True:
                self.process()
        except EOF:
            return
Пример #12
0
 def buffer(self):
     'returns a JdwpBuffer configured for this connection'
     buf = JdwpBuffer()
     buf.config(*self.sizes)
     return buf
Пример #13
0
class Connection(Thread):
    '''
    The JDWP Connection is a thread which abstracts the asynchronous JDWP protocol
    into a more synchronous one.  The thread will listen for packets using the
    supplied read function, and transmit them using the write function.  

    Requests are sent by the processor using the calling thread, with a mutex 
    used to protect the write function from concurrent access.  The requesting
    thread is then blocked waiting on a response from the processor thread.

    The Connectionor will repeatedly use the read function to receive packets, which
    will be dispatched based on whether they are responses to a previous request,
    or events.  Responses to requests will cause the requesting thread to be
    unblocked, thus simulating a synchronous request.
    '''

    def __init__(self, read, write):
        Thread.__init__(self)
        self.xmitbuf = JdwpBuffer()
        self.recvbuf = JdwpBuffer()
        self._read = read
        self.write = write
        self.initialized = False
        self.next_id = 3
        self.bindqueue = Queue()
        self.qmap = {}
        self.rmap = {}
        self.xmitlock = Lock()

    def read(self, sz):
        'read size bytes'
        if sz == 0: return ''
        pkt = self._read(sz)
        if not len(pkt): raise EOF()
        return pkt

    ###################################################### INITIALIZATION STEPS
    
    def writeIdSzReq(self):
        'write an id size request'
        return self.write(IDSZ_REQ)

    def readIdSzRes(self):
        'read an id size response'
        head = self.readHeader()
        if head[0] != 20:
            raise ProtocolError('expected size of an idsize response')
        if head[2] != 0x80:
            raise ProtocolError(
                'expected first server message to be a response'
            )
        if head[1] != 1:
            raise ProtocolError('expected first server message to be 1')

        sizes = self.recvbuf.unpack( 'iiiii', self.read(20) )
        self.sizes = sizes
        self.recvbuf.config(*sizes)
        self.xmitbuf.config(*sizes)
        return None

    def readHandshake(self):
        'read the jdwp handshake'
        data = self.read(len(HANDSHAKE_MSG))
        if data != HANDSHAKE_MSG:
            raise HandshakeError()
        
    def writeHandshake(self):
        'write the jdwp handshake'
        return self.write(HANDSHAKE_MSG)

    ############################################### READING / PROCESSING PACKETS
    
    def readHeader(self):
        'reads a header and returns [size, id, flags, event]'
        head = self.read(11)
        data = self.recvbuf.unpack(HEADER_FORMAT, head)
        data[0] -= 11
        return data
    
    def process(self):
        'invoked repeatedly by the processing thread'

        size, ident, flags, code = self.readHeader() #TODO: HANDLE CLOSE
        data = self.read(size) #TODO: HANDLE CLOSE
        try: # We process binds after receiving messages to prevent a race
            while True:
                self.processBind(*self.bindqueue.get(False))
        except EmptyQueue:
            pass

        #TODO: update binds with all from bindqueue
        
        if flags == 0x80:
            self.processResponse(ident, code, data)
        else:
            self.processRequest(ident, code, data)

    def processBind(self, qr, ident, chan):
        'internal to i/o thread; performs a query or request bind'
        if qr == 'q':
            self.qmap[ident] = chan
        elif qr == 'r':
            self.rmap[ident] = chan

    def processRequest(self, ident, code, data):
        'internal to the i/o thread w/ recv ctrl; processes incoming request'
        chan = self.rmap.get(code)
        if not chan: return #TODO
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        buf.prepareUnpack(data)
        return chan.put((ident, buf))
        
    def processResponse(self, ident, code, data):
        'internal to the i/o thread w/ recv ctrl; processes incoming response'
        chan = self.qmap.pop(ident, None)
        if not chan: return
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        buf.prepareUnpack(data)
        return chan.put((code, buf))

    def hook(self, code, chan):
        '''
        when code requests are received, they will be put in chan for
        processing
        '''

        with self.xmitlock:
            self.bindqueue.put(('r', code, chan))
        
    ####################################################### TRANSMITTING PACKETS
    
    def acquireIdent(self):
        'used internally by the processor; must have xmit control'
        ident = self.next_id
        self.next_id += 2
        return ident

    def writeContent(self, ident, flags, code, body):
        'used internally by the processor; must have xmit control'

        size = len(body) + 11
        self.xmitbuf.preparePack(11)
        data = self.xmitbuf.pack(
            HEADER_FORMAT, size, ident, flags, code
        )
        self.write(data)
        return self.write(body)

    def request(self, code, data='', timeout=None):
        'send a request, then waits for a response; returns response'
        queue = Queue()

        with self.xmitlock:
            ident = self.acquireIdent()
            self.bindqueue.put(('q', ident, queue))
            self.writeContent(ident, 0x0, code, data)
        
        try:
            return queue.get(1, timeout)
        except EmptyQueue:
            return None

    def buffer(self):
        'returns a JdwpBuffer configured for this connection'
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        return buf
        
    ################################################################# THREAD API
    
    def start(self):
        'performs handshaking and solicits configuration information'
        self.daemon = True

        if not self.initialized:
            self.writeHandshake()
            self.readHandshake()
            self.writeIdSzReq()
            self.readIdSzRes()
            self.initialized = True
            Thread.start(self)
        return None

    def run(self):
        'runs forever; overrides the default Thread.run()'
        try:
            while True:
                self.process()
        except EOF:
            return
Пример #14
0
class Connection(Thread):
    '''
    The JDWP Connection is a thread which abstracts the asynchronous[异步] JDWP protocol
    into a more synchronous one.  The thread will listen for packets using the
    supplied[提供] read function, and transmit[传送] them using the write function.  

    Requests are sent by the processor using the calling thread, with a mutex 
    used to protect the write function from concurrent[并发的] access.  The requesting
    thread is then blocked waiting on a response from the processor thread.

    The Connectionor will repeatedly use the read function to receive packets, which
    will be dispatched based on whether they are responses to a previous request,
    or events.  Responses to requests will cause the requesting thread to be
    unblocked, thus simulating a synchronous request.
    '''

    def __init__(self, read, write):
        Thread.__init__(self)
        self.xmitbuf = JdwpBuffer()  #具体实现在jdwp文件中,用C语言实现,这块需要了解C语言嵌入python语言的知识
        self.recvbuf = JdwpBuffer()
        self._read = read
        self.write = write
        self.initialized = False
        self.next_id = 3  #下一个请求id,『可能每次请求都是有序号的』
        self.bindqueue = Queue()  #定义一个先进先出的队列
        self.qmap = {}   #初始化一个空的字典
        self.rmap = {}   #初始化一个空的字典
        self.xmitlock = Lock()  #是一个互斥锁

    #读数据的函数,sz准备读取数据的长度,
    def read(self, sz):
        'read size bytes'
        if sz == 0: return ''
        pkt = self._read(sz)  #返回值是读到的数据
        if not len(pkt): raise EOF()   #如果读到的数据的长度为0,抛出EOF异常
        return pkt

    ###################################################### INITIALIZATION STEPS
    
    #写入id序列信息
    def writeIdSzReq(self):
        'write an id size request'
        return self.write(IDSZ_REQ)

	#读取各id的长度信息
    def readIdSzRes(self):
        'read an id size response'
        head = self.readHeader()  #读到的header的值是:list: [20L, 1L, 128L, 0L] [Length, Id,Flags, Error Code]
        if head[0] != 20: #id size命令的返回数据包的长度为20字节,其中包括11字节的包头长度。
            raise ProtocolError('expected size of an idsize response') #抛出协议错误异常
        if head[2] != 0x80:  #返回包包头中的Flags字段的值是固定的均为0x80即128
            raise ProtocolError(
                'expected first server message to be a response' #抛出协议错误异常
            )
        if head[1] != 1: #由于发送id size请求包的id编号是1,所以合法的返回包的编号也应用是1
            raise ProtocolError('expected first server message to be 1')  #抛出协议错误异常

        sizes = self.recvbuf.unpack( 'iiiii', self.read(20) )
        self.sizes = sizes #读取到的sizes的值是 list: [4L, 4L, 8L, 8L, 8L] 记录下各类型对象所占空间的长度
        self.recvbuf.config(*sizes) 
        self.xmitbuf.config(*sizes)
        return None

	#接收握手数据
    def readHandshake(self):
        'read the jdwp handshake'
        data = self.read(len(HANDSHAKE_MSG))
        if data != HANDSHAKE_MSG:
            raise HandshakeError()  #抛出握手失败异常
    #发送握手数据    
    def writeHandshake(self):
        'write the jdwp handshake'
        return self.write(HANDSHAKE_MSG)

    ############################################### READING / PROCESSING PACKETS
    
    #读取头,在readIdSzRes(self)函数中被调用
    def readHeader(self):
        'reads a header and returns [size, id, flags, event]'
        head = self.read(11)  
        data = self.recvbuf.unpack(HEADER_FORMAT, head)  #unpack函数在jdwp文件中实现
        data[0] -= 11
        return data
    #启动新的线程,来处理从虚拟机中返回的信息。process函数被放在一个死循环中不断调用
    def process(self):
        'invoked repeatedly by the processing thread'

        size, ident, flags, code = self.readHeader() #TODO: HANDLE CLOSE  #读取数据头,包含一下元素size、ident、flags、code
        log.debug("study", "In Connection(Thread).process size=" + str(size) + "\t ident="+ str(ident) + "\t flags=" +str(flags) + "\t code=" + str(code))
        data = self.read(size) #TODO: HANDLE CLOSE  #根据Header中的长度信息,读取具体数据。
        try: # We process binds[绑定] after receiving messages to prevent a race
            while True:
                self.processBind(*self.bindqueue.get(False)) #bindqueue.get(False)参数为False,队列将引发Empty异常
        except EmptyQueue:
            log.debug("study", "Except for Empty Queue")
            pass

        #TODO: update binds with all from bindqueue
        #对于来自虚拟机的事件消息,self.processBind(*self.bindqueue.get(False))不起作用,直接触发EmptyQueue异常,后续调用processRequest函数
        if flags == 0x80:  
            self.processResponse(ident, code, data)  #答复数据包的flag是0x80
        else:
            self.processRequest(ident, code, data)  #请求数据包的flag是0x00
    #函数调用的参数为:qr="r" ident=16484=0x4064 chan 是一个在Session类中定义的一个队列。qr="q" ident=3 其中ident是请求的编号id,调试器发往虚拟机的id从3开始
    def processBind(self, qr, ident, chan):
        'internal[内部的] to i/o thread; performs a query or request bind'
		#根据qr值的不同,以ident为关键字,以chan为值,放入不同的字典中
        log.debug("study", "In Connection(Thread).processBind qr=" + str(qr) + "\t ident=" + str(ident) + "\t chan=" + str(chan))
        log.debug("study", "++bindqueue.get  FOR q ++")
        if qr == 'q':
            self.qmap[ident] = chan  
        elif qr == 'r':
            self.rmap[ident] = chan
           

	#处理请求
    ##请求数据包的flag是0x00
    def processRequest(self, ident, code, data):
        'internal to the i/o thread w/ recv ctrl; processes incoming request'
        log.debug("study", "In Connection.processRequest ident=" + str(ident) + "\t code=" + str(code) + "\t data=")
        chan = self.rmap.get(code)  #所有中断都由该chan队列处理,每次只是从rmap读出内容,而没有将rmap对应的chan清除
        if not chan: return #TODO
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        buf.prepareUnpack(data)
        return chan.put((ident, buf)) #将解析后的数据压入队列中
     
	#处理相应,chan变量是什么类型的需要关注,其与类的队列成员变量self.bindqueue有关
    #答复数据包的flag是0x80   
    def processResponse(self, ident, code, data):
        'internal to the i/o thread w/ recv ctrl; processes incoming response'
        log.debug("study", "In Connection.processResponse ident=" + str(ident) + "\t code=" + str(code) + "\t data=")
        chan = self.qmap.pop(ident, None) #从字典中读取,并删除该数据
        if not chan: return
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        buf.prepareUnpack(data)
        return chan.put((code, buf))

	#调用的实际情况为:conn.hook(0x4064, self.evtq),其中self.evtq是一个队列
    def hook(self, code, chan):
        '''
        when code requests are received, they will be put in chan for
        processing
        '''

		#使用锁
        with self.xmitlock:
            self.bindqueue.put(('r', code, chan)) #加入一个先进先出的队列
            log.debug("study", "++ for hook function bindqueue.put  FOR r ++ code=" + str(code))
        
    ####################################################### TRANSMITTING PACKETS
    
	#申请一个请求id
    def acquireIdent(self):
        'used internally by the processor; must have xmit[传输] control'
        ident = self.next_id
        self.next_id += 2
        return ident

	#发送[写入]指定的数据
    def writeContent(self, ident, flags, code, body):
        'used internally by the processor; must have xmit control'

        size = len(body) + 11
        self.xmitbuf.preparePack(11)
        data = self.xmitbuf.pack(
            HEADER_FORMAT, size, ident, flags, code
        )
        self.write(data)
        return self.write(body)

	#构造请求
    def request(self, code, data='', timeout=None):
        'send a request, then waits for a response; returns response'
        queue = Queue()
        log.debug("study", "In Connection.request code=" + str(code) + "\t data=" + str(data))
        with self.xmitlock:
            ident = self.acquireIdent()
            self.bindqueue.put(('q', ident, queue)) #每发送一个请求向bindqueue中压入一个数据
            log.debug("study", "++bindqueue.put  FOR q ++")
            self.writeContent(ident, 0x0, code, data)
        
        try:
            log.debug("study", "wait_code:" + str(code))
            return queue.get(1, timeout)  #向虚拟机发出指令后一直处于等待状态,知道queue队列中出现返回信息,接下来处理
        except EmptyQueue:
            return None, None

    def buffer(self):
        'returns a JdwpBuffer configured for this connection'
        buf = JdwpBuffer()
        buf.config(*self.sizes)
        return buf
        
    ################################################################# THREAD API
    
    def start(self):
        'performs handshaking and solicits[恳求] configuration information'
        self.daemon = True  #守护线程

        if not self.initialized: #如果为false初始化尚未完成,完成下面初始化工作
            self.writeHandshake()
            self.readHandshake()
            self.writeIdSzReq()
            self.readIdSzRes()
            self.initialized = True #确认完成初始话
            Thread.start(self)
        return None

    def run(self):
        'runs forever; overrides the default Thread.run()'
        try:
            while True:
                self.process()
        except EOF:
            return