private Scan createScan(String applicationName, Range range, boolean scanBackward) {
    Scan scan = new Scan();
    scan.setCaching(this.scanCacheSize);

    byte[] bApplicationName = Bytes.toBytes(applicationName);
    byte[] traceIndexStartKey = SpanUtils.getTraceIndexRowKey(bApplicationName, range.getFrom());
    byte[] traceIndexEndKey = SpanUtils.getTraceIndexRowKey(bApplicationName, range.getTo());

    if (scanBackward) {
      // start key is replaced by end key because key has been reversed
      scan.setStartRow(traceIndexEndKey);
      scan.setStopRow(traceIndexStartKey);
    } else {
      scan.setReversed(true);
      scan.setStartRow(traceIndexStartKey);
      scan.setStopRow(traceIndexEndKey);
    }

    scan.addFamily(HBaseTables.APPLICATION_TRACE_INDEX_CF_TRACE);
    scan.setId("ApplicationTraceIndexScan");

    // toString() method of Scan converts a message to json format so it is slow for the first time.
    logger.trace("create scan:{}", scan);
    return scan;
  }
Пример #2
0
 public static Scan newScan(Scan scan) {
   try {
     Scan newScan = new Scan(scan);
     // Clone the underlying family map instead of sharing it between
     // the existing and cloned Scan (which is the retarded default
     // behavior).
     TreeMap<byte[], NavigableSet<byte[]>> existingMap =
         (TreeMap<byte[], NavigableSet<byte[]>>) scan.getFamilyMap();
     Map<byte[], NavigableSet<byte[]>> clonedMap =
         new TreeMap<byte[], NavigableSet<byte[]>>(existingMap);
     newScan.setFamilyMap(clonedMap);
     // Carry over the reversed attribute
     newScan.setReversed(scan.isReversed());
     newScan.setSmall(scan.isSmall());
     return newScan;
   } catch (IOException e) {
     throw new RuntimeException(e);
   }
 }
Пример #3
0
 // Start/stop row must be swapped if scan is being done in reverse
 public static void setupReverseScan(Scan scan) {
   if (isReversed(scan)) {
     byte[] startRow = scan.getStartRow();
     byte[] stopRow = scan.getStopRow();
     byte[] newStartRow = startRow;
     byte[] newStopRow = stopRow;
     if (startRow.length != 0) {
       /*
        * Must get previous key because this is going from an inclusive start key to an exclusive stop key, and
        * we need the start key to be included. We get the previous key by decrementing the last byte by one.
        * However, with variable length data types, we need to fill with the max byte value, otherwise, if the
        * start key is 'ab', we lower it to 'aa' which would cause 'aab' to be included (which isn't correct).
        * So we fill with a 0xFF byte to prevent this. A single 0xFF would be enough for our primitive types (as
        * that byte wouldn't occur), but for an arbitrary VARBINARY key we can't know how many bytes to tack
        * on. It's lame of HBase to force us to do this.
        */
       newStartRow =
           Arrays.copyOf(startRow, startRow.length + MAX_FILL_LENGTH_FOR_PREVIOUS_KEY.length);
       if (ByteUtil.previousKey(newStartRow, startRow.length)) {
         System.arraycopy(
             MAX_FILL_LENGTH_FOR_PREVIOUS_KEY,
             0,
             newStartRow,
             startRow.length,
             MAX_FILL_LENGTH_FOR_PREVIOUS_KEY.length);
       } else {
         newStartRow = HConstants.EMPTY_START_ROW;
       }
     }
     if (stopRow.length != 0) {
       // Must add null byte because we need the start to be exclusive while it was inclusive
       newStopRow = ByteUtil.concat(stopRow, QueryConstants.SEPARATOR_BYTE_ARRAY);
     }
     scan.setStartRow(newStopRow);
     scan.setStopRow(newStartRow);
     scan.setReversed(true);
   }
 }