Example #1
0
 def _process_event(self, ts, cpuId, event):
     ExecutionModel.setCurrentEventData(ts, cpuId)
     hookList = self.__hooks[event.name]
     for hook in hookList:
         hook(event, self.__payload)
     if self.__payload:
         cpuId = RuntimeModel.getVirtualCPUId(event)
         ParaverTrace.emitEvent(ts, cpuId, self.__payload)
     self.__payload.clear()
    def hook_flush(self, event, _):
        start = event["start"]
        end = event["end"]

        # In this view we are not emiting events trough the "payload" variable,
        # but we are emitting events directly. That's because we don't want to
        # use the current event timestamp as the extare timestamp but we want
        # to use the event's fields as timestamps. It is safe to do so becaue
        # on flushing, we know that no events could be emitted between the last
        # processed event and now, basically because nanos6 was flushing the
        # buffer :-)

        cpuId = RuntimeModel.getVirtualCPUId(event)
        ParaverTrace.emitEvent(start, cpuId, [(ExtraeEventTypes.CTF_FLUSH, 1)])
        ParaverTrace.emitEvent(end, cpuId, [(ExtraeEventTypes.CTF_FLUSH, 0)])
Example #3
0
    def _process_first_message(self):
        msg = next(self._it)
        if type(msg) is bt2._EventMessageConst:
            clk = msg.default_clock_snapshot
            absoluteStartTime = clk.clock_class.offset.seconds
            ts = clk.value - 1  # see comments below
            assert (ts >= 0)
            cpuList = str(msg.event.stream.trace.environment["cpu_list"])
            binaryName = msg.event.stream.trace.environment["binary_name"]
            pid = msg.event.stream.trace.environment["pid"]
            traceName = "trace_" + str(binaryName) + "_" + str(pid)

            # initialize paraver trace
            ParaverTrace.addTraceName(traceName)
            ParaverTrace.addAbsoluteStartTime(absoluteStartTime)
            ParaverTrace.addStartTime(ts)
            ParaverTrace.addCPUList(cpuList)
            ParaverTrace.addBinaryName(binaryName)
            ParaverTrace.initalizeTraceFiles()

            # Initialize both Kernel and Runtime Models. The Kernel Model must
            # be initalized before Paravare views are created
            KernelModel.initialize()
            RuntimeModel.initialize()

            # Create Paraver Views
            self.__paraverViews = [
                pv.ParaverViewRuntimeCode(),
                pv.ParaverViewRuntimeBusyWaiting(),
                pv.ParaverViewRuntimeTasks(),
                pv.ParaverViewTaskLabel(),
                pv.ParaverViewTaskSource(),
                pv.ParaverViewTaskId(),
                pv.ParaverViewHardwareCounters(),
                pv.ParaverViewThreadId(),
                pv.ParaverViewRuntimeSubsystems(),
                pv.ParaverViewCTFFlush(),
                #pv.ParaverViewNumberOfReadyTasks(),
                pv.ParaverViewNumberOfCreatedTasks(),
                pv.ParaverViewNumberOfBlockedTasks(),
                pv.ParaverViewNumberOfRunningTasks(),
                pv.ParaverViewNumberOfCreatedThreads(),
                pv.ParaverViewNumberOfRunningThreads(),
                pv.ParaverViewNumberOfBlockedThreads(),
                pv.ParaverViewKernelThreadID(),
                pv.ParaverViewKernelPreemptions(),
                pv.ParaverViewKernelSyscalls(),
            ]

            # Install event processing hooks
            self.installHooks(KernelModel.preHooks())
            self.installHooks(RuntimeModel.preHooks())
            for view in self.__paraverViews:
                self.installHooks(view.hooks())
            self.installHooks(RuntimeModel.postHooks())
            self.installHooks(KernelModel.postHooks())

            # redirect message processing
            self.__process_message = self._process_other_message

            # compute set of starting events
            for view in self.__paraverViews:
                view.start(self.__payload)
            # We emit a set of initial events one nanosecond before the first
            # event is encountered to avoid overlapping with the extrae events
            # derived from the first ctf event.
            ParaverTrace.emitEvent(ts, 0, self.__payload)
            self.__payload.clear()

        self._consume_message(msg)
 def hook_exitBusyWait(self, event, payload):
     thread = RuntimeModel.getCurrentThread(event)
     thread.isBusyWaiting = 0
     payload.append(
         (ExtraeEventTypes.RUNTIME_BUSYWAITING, RuntimeActivity.End))
 def hook_threadResume(self, event, payload):
     thread = RuntimeModel.getCurrentThread(event)
     if thread.isBusyWaiting:
         payload.append((ExtraeEventTypes.RUNTIME_BUSYWAITING,
                         RuntimeActivity.BusyWaiting))
 def getEventStack(self, event):
     thread = RuntimeModel.getCurrentThread(event)
     stack = thread.eventStack
     assert (stack != None)
     return stack
 def hook_initExternalThreadStack(self, event, payload):
     tid = event["tid"]
     thread = RuntimeModel.getThread(tid)
     thread.eventStack = [self.Status.Idle]
 def hook_threadSuspend(self, event, payload):
     task = RuntimeModel.getCurrentTask(event)
     if task.isRunning():
         payload.append(
             (ExtraeEventTypes.RUNNING_TASK_ID, RuntimeActivity.End))
 def hook_threadResume(self, event, payload):
     task = RuntimeModel.getCurrentTask(event)
     if task.isRunning():
         payload.append((ExtraeEventTypes.RUNNING_TASK_ID, task.id))
Example #10
0
 def hook_taskExecute(self, event, payload):
     task = RuntimeModel.getCurrentTask(event)
     payload.append((ExtraeEventTypes.RUNNING_TASK_ID, task.id))