/** * Given a scan and a key range, return a new Scan whose range is truncated to only include keys * in that range. Returns null if the Scan does not overlap the given range. */ private static final Scan truncateScan(Scan scan, byte[] rangeStart, byte[] rangeEnd) { byte[] scanStart = scan.getStartRow(); byte[] scanEnd = scan.getStopRow(); if (scanEnd.length > 0 && bytesCompare(scanEnd, rangeStart) <= 0) { // The entire scan range is before the entire cube key range return null; } else if (scanStart.length > 0 && bytesCompare(scanStart, rangeEnd) >= 0) { // The entire scan range is after the entire cube key range return null; } else { // Now we now that the scan range at least partially overlaps the cube key range. Scan truncated; try { truncated = new Scan(scan); // make a copy, don't modify input scan } catch (IOException e) { throw new RuntimeException(); // This is not plausible } if (scanStart.length == 0 || bytesCompare(rangeStart, scanStart) > 0) { // The scan includes extra keys at the beginning that are not part of the cube. Move // the scan start point so that it only touches keys belonging to the cube. truncated.setStartRow(rangeStart); } if (scanEnd.length == 0 || bytesCompare(rangeEnd, scanEnd) < 0) { // The scan includes extra keys at the end that are not part of the cube. Move the // scan end point so it only touches keys belonging to the cube. truncated.setStopRow(rangeEnd); } return truncated; } }
/** * @param scan the scan specification * @throws Exception */ public static ScannerModel fromScan(Scan scan) throws Exception { ScannerModel model = new ScannerModel(); model.setStartRow(scan.getStartRow()); model.setEndRow(scan.getStopRow()); Map<byte[], NavigableSet<byte[]>> families = scan.getFamilyMap(); if (families != null) { for (Map.Entry<byte[], NavigableSet<byte[]>> entry : families.entrySet()) { if (entry.getValue() != null) { for (byte[] qualifier : entry.getValue()) { model.addColumn(Bytes.add(entry.getKey(), COLUMN_DIVIDER, qualifier)); } } else { model.addColumn(entry.getKey()); } } } model.setStartTime(scan.getTimeRange().getMin()); model.setEndTime(scan.getTimeRange().getMax()); int caching = scan.getCaching(); if (caching > 0) { model.setBatch(caching); } int maxVersions = scan.getMaxVersions(); if (maxVersions > 0) { model.setMaxVersions(maxVersions); } Filter filter = scan.getFilter(); if (filter != null) { model.setFilter(stringifyFilter(filter)); } return model; }
protected boolean checkScanStopRow(final byte[] endKey) { if (this.scan.getStopRow().length > 0) { byte[] stopRow = scan.getStopRow(); int cmp = Bytes.compareTo(stopRow, 0, stopRow.length, endKey, 0, endKey.length); if (cmp <= 0) { return true; } } return false; }
@Override public Builder adapt(Scan scan, ReadHooks readHooks) { throwIfUnsupportedScan(scan); // For gets, startRow == stopRow. There's no need to create a new ByteString for stopRow RowFilter filter = buildFilter(scan, readHooks); return ReadRowsRequest.newBuilder() .setFilter(filter) .setRowRange( RowRange.newBuilder() .setStartKey(ByteString.copyFrom(scan.getStartRow())) .setEndKey(ByteString.copyFrom(scan.getStopRow()))); }
// 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); } }
public static boolean intersectScanRange( Scan scan, byte[] startKey, byte[] stopKey, boolean useSkipScan) { boolean mayHaveRows = false; int offset = 0; if (ScanUtil.isLocalIndex(scan)) { offset = startKey.length != 0 ? startKey.length : stopKey.length; } byte[] existingStartKey = scan.getStartRow(); byte[] existingStopKey = scan.getStopRow(); if (existingStartKey.length > 0) { if (startKey.length == 0 || Bytes.compareTo(existingStartKey, startKey) > 0) { startKey = existingStartKey; } } else { mayHaveRows = true; } if (existingStopKey.length > 0) { if (stopKey.length == 0 || Bytes.compareTo(existingStopKey, stopKey) < 0) { stopKey = existingStopKey; } } else { mayHaveRows = true; } scan.setStartRow(startKey); scan.setStopRow(stopKey); if (offset > 0 && useSkipScan) { byte[] temp = null; if (startKey.length != 0) { temp = new byte[startKey.length - offset]; System.arraycopy(startKey, offset, temp, 0, startKey.length - offset); startKey = temp; } if (stopKey.length != 0) { temp = new byte[stopKey.length - offset]; System.arraycopy(stopKey, offset, temp, 0, stopKey.length - offset); stopKey = temp; } } mayHaveRows = mayHaveRows || Bytes.compareTo(scan.getStartRow(), scan.getStopRow()) < 0; // If the scan is using skip scan filter, intersect and replace the filter. if (mayHaveRows && useSkipScan) { Filter filter = scan.getFilter(); if (filter instanceof SkipScanFilter) { SkipScanFilter oldFilter = (SkipScanFilter) filter; SkipScanFilter newFilter = oldFilter.intersect(startKey, stopKey); if (newFilter == null) { return false; } // Intersect found: replace skip scan with intersected one scan.setFilter(newFilter); } else if (filter instanceof FilterList) { FilterList oldList = (FilterList) filter; FilterList newList = new FilterList(FilterList.Operator.MUST_PASS_ALL); for (Filter f : oldList.getFilters()) { if (f instanceof SkipScanFilter) { SkipScanFilter newFilter = ((SkipScanFilter) f).intersect(startKey, stopKey); if (newFilter == null) { return false; } newList.addFilter(newFilter); } else { newList.addFilter(f); } } scan.setFilter(newList); } } return mayHaveRows; }
@Override public List<String> copQueryAvailableNear( String timestamp, final double latitude, final double longitude, final double radius) { this.getStatLog(STAT_FILE_NAME); this.getCSVLog(this.FILE_NAME_PREFIX, 0); this.getCSVLog(this.FILE_NAME_PREFIX, 1); this.getCSVLog(this.FILE_NAME_PREFIX, 2); this.timePhase.clear(); try { /** Step1** Call back class definition * */ class BixiCallBack implements Batch.Callback<RCopResult> { RCopResult res = new RCopResult(); int count = 0; QueryAbstraction query = null; public BixiCallBack(QueryAbstraction query) { this.query = query; } @Override public void update(byte[] region, byte[] row, RCopResult result) { long current = System.currentTimeMillis(); count++; res.getRes().addAll(result.getRes()); // to verify the error when large data res.setStart(result.getStart()); res.setEnd(result.getEnd()); res.setRows((res.getRows() + result.getRows())); res.setCells(res.getCells() + result.getCells()); // System.out.println((count++) + ": come back region: "+ Bytes.toString(region) + "; // result: "+ result.size()); /* String outStr="count=>"+count+";start=>"+result.getStart()+";end=>"+result.getEnd()+";process=>"+(result.getEnd()-result.getStart())+ ";tranmission=>"+(System.currentTimeMillis()-result.getEnd())+ ";region=>"+Bytes.toString(region)+ ";row=>"+result.getRows()+";result=>"+result.getRes().size(); this.query.writeStat(outStr); outStr = query.regions.get(Bytes.toString(region)).toString(); this.query.writeStat(outStr); */ // write them into csv file String outStr = ""; outStr += "within," + "cop," + result.getParameter() + "," + result.getStart() + "," + result.getEnd() + "," + current + "," + result.getRows() + "," + result.getCells() + "," + "," + result.getKvLength() + result.getRes().size() + "," + this.query.regionAndRS.get(Bytes.toString(region)) + "," + Bytes.toString(region); this.query.writeCSVLog(outStr, 1); } } BixiCallBack callBack = new BixiCallBack(this); /** Step2** generate the scan ********** */ long s_time = System.currentTimeMillis(); this.timePhase.add(s_time); // build up the Raster XRaster raster = new XRaster(this.space, this.min_size_of_height, this.max_num_of_column); // match the query area in Raster to get the row range and column // range long match_s = System.currentTimeMillis(); XBox[] match_boxes = raster.match(latitude, longitude, radius); long match_time = System.currentTimeMillis() - match_s; String[] rowRange = new String[2]; rowRange[0] = match_boxes[0].getRow(); rowRange[1] = match_boxes[1].getRow() + "-*"; String[] c = raster.getColumns(match_boxes[0], match_boxes[1]); // generate the scan final Scan scan = hbaseUtil.generateScan( rowRange, null, new String[] {BixiConstant.LOCATION_FAMILY_NAME}, c, 1000000); /** Step3** send out the query to trigger the corresponding function in Coprocessor*** */ this.timePhase.add(System.currentTimeMillis()); hbaseUtil .getHTable() .coprocessorExec( BixiProtocol.class, scan.getStartRow(), scan.getStopRow(), new Batch.Call<BixiProtocol, RCopResult>() { public RCopResult call(BixiProtocol instance) throws IOException { return instance.copQueryNeighbor4LS2(scan, latitude, longitude, radius); }; }, callBack); long e_time = System.currentTimeMillis(); this.timePhase.add(e_time); long exe_time = e_time - s_time; /* System.out.println("exe_time=>"+exe_time+";result=>"+callBack.res.getRes().size()); String outStr = "m=>cop;"+"radius=>"+radius+";exe_time=>"+exe_time+";result=>"+callBack.res.getRes().size(); this.writeStat(outStr);*/ // write to csv file String outStr = ""; outStr += "within," + "cop," + callBack.res.getCells() + "," + callBack.res.getRes().size() + "," + exe_time + "," + callBack.res.getRows() + "," + match_time + "," + this.min_size_of_height + "," + radius; this.writeCSVLog(outStr, 0); String timeStr = "within,cop," + radius + ","; for (int i = 0; i < this.timePhase.size(); i++) { timeStr += this.timePhase.get(i) + ","; } this.writeCSVLog(timeStr, 2); return callBack.res.getRes(); } catch (Exception e) { e.printStackTrace(); } catch (Throwable ee) { ee.printStackTrace(); } finally { hbaseUtil.closeTableHandler(); this.closeStatLog(); this.closeCSVLog(); } return null; }
@Override public String copQueryPoint(final double latitude, final double longitude) { this.getStatLog(STAT_FILE_NAME); long s_time = System.currentTimeMillis(); try { /** Step1** Call back class definition * */ class BixiCallBack implements Batch.Callback<String> { String res = null; int count = 0; QueryAbstraction query = null; public BixiCallBack(QueryAbstraction query) { this.query = query; } @Override public void update(byte[] region, byte[] row, String result) { count++; String outStr = "endTime=>" + System.currentTimeMillis() + ";region=>" + Bytes.toString(region) + ";count=>" + count + ";result=>" + result; this.query.writeStat(outStr); outStr = query.regions.get(Bytes.toString(region)).toString(); this.query.writeStat(outStr); res = result; } } BixiCallBack callBack = new BixiCallBack(this); /** Step2** generate the scan ********** */ // build up the Raster XRaster raster = new XRaster(this.space, this.min_size_of_height, this.max_num_of_column); XBox match_box = raster.locate(latitude, Math.abs(longitude)); System.out.println("match_box is : " + match_box.toString()); String[] rowRange = new String[2]; rowRange[0] = match_box.getRow(); rowRange[1] = match_box.getRow() + "0"; // generate the scan final Scan scan = hbaseUtil.generateScan( rowRange, null, new String[] {BixiConstant.LOCATION_FAMILY_NAME}, new String[] {match_box.getColumn()}, 100000); /** Step3** send out the query to trigger the corresponding function in Coprocessor*** */ hbaseUtil .getHTable() .coprocessorExec( BixiProtocol.class, scan.getStartRow(), scan.getStopRow(), new Batch.Call<BixiProtocol, String>() { public String call(BixiProtocol instance) throws IOException { return instance.copQueryPoint4LS2(scan, latitude, longitude); }; }, callBack); long e_time = System.currentTimeMillis(); long exe_time = e_time - s_time; // TODO store the time into database System.out.println("exe_time=>" + exe_time + ";result=>" + callBack.res); String outStr = "q=point;m=>cop;" + ";exe_time=>" + exe_time + ";result=>" + callBack.res; this.writeStat(outStr); return callBack.res; } catch (Exception e) { e.printStackTrace(); } catch (Throwable ee) { ee.printStackTrace(); } finally { hbaseUtil.closeTableHandler(); this.closeStatLog(); } return null; }
public Scan intersectScan( Scan scan, final byte[] originalStartKey, final byte[] originalStopKey, final int keyOffset, boolean crossesRegionBoundary) { byte[] startKey = originalStartKey; byte[] stopKey = originalStopKey; if (stopKey.length > 0 && Bytes.compareTo(startKey, stopKey) >= 0) { return null; } boolean mayHaveRows = false; // Keep the keys as they are if we have a point lookup, as we've already resolved the // salt bytes in that case. final int scanKeyOffset = this.isSalted && !this.isPointLookup ? SaltingUtil.NUM_SALTING_BYTES : 0; assert (scanKeyOffset == 0 || keyOffset == 0); // Total offset for startKey/stopKey. Either 1 for salted tables or the prefix length // of the current region for local indexes. We'll never have a case where a table is // both salted and local. final int totalKeyOffset = scanKeyOffset + keyOffset; byte[] prefixBytes = ByteUtil.EMPTY_BYTE_ARRAY; if (totalKeyOffset > 0) { prefixBytes = ScanUtil.getPrefix(startKey, totalKeyOffset); /* * If our startKey to stopKey crosses a region boundary consider everything after the startKey as our scan * is always done within a single region. This prevents us from having to prefix the key prior to knowing * whether or not there may be an intersection. We can't calculate whether or not we've crossed a region * boundary for local indexes, because we don't know the key offset of the next region, but only for the * current one (which is the one passed in). If the next prefix happened to be a subset of the previous * prefix, then this wouldn't detect that we crossed a region boundary. */ if (crossesRegionBoundary) { stopKey = ByteUtil.EMPTY_BYTE_ARRAY; } } int scanStartKeyOffset = scanKeyOffset; byte[] scanStartKey = scan == null ? ByteUtil.EMPTY_BYTE_ARRAY : scan.getStartRow(); // Compare ignoring key prefix and salt byte if (scanStartKey.length > 0) { if (startKey.length > 0 && Bytes.compareTo( scanStartKey, scanKeyOffset, scanStartKey.length - scanKeyOffset, startKey, totalKeyOffset, startKey.length - totalKeyOffset) < 0) { scanStartKey = startKey; scanStartKeyOffset = totalKeyOffset; } } else { scanStartKey = startKey; scanStartKeyOffset = totalKeyOffset; mayHaveRows = true; } int scanStopKeyOffset = scanKeyOffset; byte[] scanStopKey = scan == null ? ByteUtil.EMPTY_BYTE_ARRAY : scan.getStopRow(); if (scanStopKey.length > 0) { if (stopKey.length > 0 && Bytes.compareTo( scanStopKey, scanKeyOffset, scanStopKey.length - scanKeyOffset, stopKey, totalKeyOffset, stopKey.length - totalKeyOffset) > 0) { scanStopKey = stopKey; scanStopKeyOffset = totalKeyOffset; } } else { scanStopKey = stopKey; scanStopKeyOffset = totalKeyOffset; mayHaveRows = true; } mayHaveRows = mayHaveRows || Bytes.compareTo( scanStartKey, scanStartKeyOffset, scanStartKey.length - scanStartKeyOffset, scanStopKey, scanStopKeyOffset, scanStopKey.length - scanStopKeyOffset) < 0; if (!mayHaveRows) { return null; } if (originalStopKey.length != 0 && scanStopKey.length == 0) { scanStopKey = originalStopKey; } Filter newFilter = null; // If the scan is using skip scan filter, intersect and replace the filter. if (scan == null || this.useSkipScanFilter()) { byte[] skipScanStartKey = scanStartKey; byte[] skipScanStopKey = scanStopKey; // If we have a keyOffset and we've used the startKey/stopKey that // were passed in (which have the prefix) for the above range check, // we need to remove the prefix before running our intersect method. // TODO: we could use skipScanFilter.setOffset(keyOffset) if both // the startKey and stopKey were used above *and* our intersect // method honored the skipScanFilter.offset variable. if (scanKeyOffset > 0) { if (skipScanStartKey != originalStartKey) { // original already has correct salt byte skipScanStartKey = replaceSaltByte(skipScanStartKey, prefixBytes); } if (skipScanStopKey != originalStopKey) { skipScanStopKey = replaceSaltByte(skipScanStopKey, prefixBytes); } } else if (keyOffset > 0) { if (skipScanStartKey == originalStartKey) { skipScanStartKey = stripPrefix(skipScanStartKey, keyOffset); } if (skipScanStopKey == originalStopKey) { skipScanStopKey = stripPrefix(skipScanStopKey, keyOffset); } } if (scan == null) { return filter.hasIntersect(skipScanStartKey, skipScanStopKey) ? HAS_INTERSECTION : null; } Filter filter = scan.getFilter(); SkipScanFilter newSkipScanFilter = null; if (filter instanceof SkipScanFilter) { SkipScanFilter oldSkipScanFilter = (SkipScanFilter) filter; newFilter = newSkipScanFilter = oldSkipScanFilter.intersect(skipScanStartKey, skipScanStopKey); if (newFilter == null) { return null; } } else if (filter instanceof FilterList) { FilterList oldList = (FilterList) filter; FilterList newList = new FilterList(FilterList.Operator.MUST_PASS_ALL); newFilter = newList; for (Filter f : oldList.getFilters()) { if (f instanceof SkipScanFilter) { newSkipScanFilter = ((SkipScanFilter) f).intersect(skipScanStartKey, skipScanStopKey); if (newSkipScanFilter == null) { return null; } newList.addFilter(newSkipScanFilter); } else { newList.addFilter(f); } } } // TODO: it seems that our SkipScanFilter or HBase runs into problems if we don't // have an enclosing range when we do a point lookup. if (isPointLookup) { scanStartKey = ScanUtil.getMinKey(schema, newSkipScanFilter.getSlots(), slotSpan); scanStopKey = ScanUtil.getMaxKey(schema, newSkipScanFilter.getSlots(), slotSpan); } } if (newFilter == null) { newFilter = scan.getFilter(); } Scan newScan = ScanUtil.newScan(scan); newScan.setFilter(newFilter); // If we have an offset (salted table or local index), we need to make sure to // prefix our scan start/stop row by the prefix of the startKey or stopKey that // were passed in. Our scan either doesn't have the prefix or has a placeholder // for it. if (totalKeyOffset > 0) { if (scanStartKey != originalStartKey) { scanStartKey = prefixKey(scanStartKey, scanKeyOffset, prefixBytes, keyOffset); } if (scanStopKey != originalStopKey) { scanStopKey = prefixKey(scanStopKey, scanKeyOffset, prefixBytes, keyOffset); } } // Don't let the stopRow of the scan go beyond the originalStopKey if (originalStopKey.length > 0 && Bytes.compareTo(scanStopKey, originalStopKey) > 0) { scanStopKey = originalStopKey; } if (scanStopKey.length > 0 && Bytes.compareTo(scanStartKey, scanStopKey) >= 0) { return null; } newScan.setAttribute(SCAN_ACTUAL_START_ROW, scanStartKey); newScan.setStartRow(scanStartKey); newScan.setStopRow(scanStopKey); if (keyOffset > 0) { newScan.setAttribute(STARTKEY_OFFSET, Bytes.toBytes(keyOffset)); } return newScan; }