protected void layoutFooter(Page page) { ServletUtil.doLayoutFooter( page, (footnotes == null ? null : footnotes.iterator()), getLockssApp().getVersionInfo()); if (footnotes != null) { footnotes.removeAllElements(); } }
public synchronized TaskReport[] getReduceTaskReports(String jobid) { JobInProgress job = (JobInProgress) jobs.get(jobid); if (job == null) { return new TaskReport[0]; } else { Vector reports = new Vector(); Vector completeReduceTasks = job.reportTasksInProgress(false, true); for (Iterator it = completeReduceTasks.iterator(); it.hasNext(); ) { TaskInProgress tip = (TaskInProgress) it.next(); reports.add(tip.generateSingleReport()); } Vector incompleteReduceTasks = job.reportTasksInProgress(false, false); for (Iterator it = incompleteReduceTasks.iterator(); it.hasNext(); ) { TaskInProgress tip = (TaskInProgress) it.next(); reports.add(tip.generateSingleReport()); } return (TaskReport[]) reports.toArray(new TaskReport[reports.size()]); } }
/** * A tracker wants to know if there's a Task to run. Returns a task we'd like the TaskTracker to * execute right now. * * <p>Eventually this function should compute load on the various TaskTrackers, and incorporate * knowledge of DFS file placement. But for right now, it just grabs a single item out of the * pending task list and hands it back. */ public synchronized Task pollForNewTask(String taskTracker) { // // Compute average map and reduce task numbers across pool // int avgMaps = 0; int avgReduces = 0; int numTaskTrackers; TaskTrackerStatus tts; synchronized (taskTrackers) { numTaskTrackers = taskTrackers.size(); tts = (TaskTrackerStatus) taskTrackers.get(taskTracker); } if (numTaskTrackers > 0) { avgMaps = totalMaps / numTaskTrackers; avgReduces = totalReduces / numTaskTrackers; } int totalCapacity = numTaskTrackers * maxCurrentTasks; // // Get map + reduce counts for the current tracker. // if (tts == null) { LOG.warning("Unknown task tracker polling; ignoring: " + taskTracker); return null; } int numMaps = tts.countMapTasks(); int numReduces = tts.countReduceTasks(); // // In the below steps, we allocate first a map task (if appropriate), // and then a reduce task if appropriate. We go through all jobs // in order of job arrival; jobs only get serviced if their // predecessors are serviced, too. // // // We hand a task to the current taskTracker if the given machine // has a workload that's equal to or less than the averageMaps // +/- TASK_ALLOC_EPSILON. (That epsilon is in place in case // there is an odd machine that is failing for some reason but // has not yet been removed from the pool, making capacity seem // larger than it really is.) // synchronized (jobsByArrival) { if ((numMaps < maxCurrentTasks) && (numMaps <= (avgMaps + TASK_ALLOC_EPSILON))) { int totalNeededMaps = 0; for (Iterator it = jobsByArrival.iterator(); it.hasNext(); ) { JobInProgress job = (JobInProgress) it.next(); if (job.getStatus().getRunState() != JobStatus.RUNNING) { continue; } Task t = job.obtainNewMapTask(taskTracker, tts); if (t != null) { return t; } // // Beyond the highest-priority task, reserve a little // room for failures and speculative executions; don't // schedule tasks to the hilt. // totalNeededMaps += job.desiredMaps(); double padding = 0; if (totalCapacity > MIN_SLOTS_FOR_PADDING) { padding = Math.min(maxCurrentTasks, totalNeededMaps * PAD_FRACTION); } if (totalNeededMaps + padding >= totalCapacity) { break; } } } // // Same thing, but for reduce tasks // if ((numReduces < maxCurrentTasks) && (numReduces <= (avgReduces + TASK_ALLOC_EPSILON))) { int totalNeededReduces = 0; for (Iterator it = jobsByArrival.iterator(); it.hasNext(); ) { JobInProgress job = (JobInProgress) it.next(); if (job.getStatus().getRunState() != JobStatus.RUNNING) { continue; } Task t = job.obtainNewReduceTask(taskTracker, tts); if (t != null) { return t; } // // Beyond the highest-priority task, reserve a little // room for failures and speculative executions; don't // schedule tasks to the hilt. // totalNeededReduces += job.desiredReduces(); double padding = 0; if (totalCapacity > MIN_SLOTS_FOR_PADDING) { padding = Math.min(maxCurrentTasks, totalNeededReduces * PAD_FRACTION); } if (totalNeededReduces + padding >= totalCapacity) { break; } } } } return null; }