private static Result getErrorResult(byte[] row, long timestamp, int errorCode) { byte[] errorCodeBuf = new byte[PDataType.INTEGER.getByteSize()]; PDataType.INTEGER.getCodec().encodeInt(errorCode, errorCodeBuf, 0); return new Result( Collections.singletonList( KeyValueUtil.newKeyValue( row, PhoenixDatabaseMetaData.SEQUENCE_FAMILY_BYTES, QueryConstants.EMPTY_COLUMN_BYTES, timestamp, errorCodeBuf))); }
/** * Use PreIncrement hook of BaseRegionObserver to overcome deficiencies in Increment * implementation (HBASE-10254): 1) Lack of recognition and identification of when the key value * to increment doesn't exist 2) Lack of the ability to set the timestamp of the updated key * value. Works the same as existing region.increment(), except assumes there is a single column * to increment and uses Phoenix LONG encoding. * * @author jtaylor * @since 3.0.0 */ @Override public Result preIncrement( final ObserverContext<RegionCoprocessorEnvironment> e, final Increment increment) throws IOException { RegionCoprocessorEnvironment env = e.getEnvironment(); // We need to set this to prevent region.increment from being called e.bypass(); e.complete(); HRegion region = env.getRegion(); byte[] row = increment.getRow(); TimeRange tr = increment.getTimeRange(); region.startRegionOperation(); try { Integer lid = region.getLock(null, row, true); try { long maxTimestamp = tr.getMax(); if (maxTimestamp == HConstants.LATEST_TIMESTAMP) { maxTimestamp = EnvironmentEdgeManager.currentTimeMillis(); tr = new TimeRange(tr.getMin(), maxTimestamp); } Get get = new Get(row); get.setTimeRange(tr.getMin(), tr.getMax()); for (Map.Entry<byte[], NavigableMap<byte[], Long>> entry : increment.getFamilyMap().entrySet()) { byte[] cf = entry.getKey(); for (byte[] cq : entry.getValue().keySet()) { get.addColumn(cf, cq); } } Result result = region.get(get); if (result.isEmpty()) { return getErrorResult( row, maxTimestamp, SQLExceptionCode.SEQUENCE_UNDEFINED.getErrorCode()); } KeyValue currentValueKV = Sequence.getCurrentValueKV(result); KeyValue incrementByKV = Sequence.getIncrementByKV(result); KeyValue cacheSizeKV = Sequence.getCacheSizeKV(result); long value = PDataType.LONG .getCodec() .decodeLong(currentValueKV.getBuffer(), currentValueKV.getValueOffset(), null); long incrementBy = PDataType.LONG .getCodec() .decodeLong(incrementByKV.getBuffer(), incrementByKV.getValueOffset(), null); int cacheSize = PDataType.INTEGER .getCodec() .decodeInt(cacheSizeKV.getBuffer(), cacheSizeKV.getValueOffset(), null); value += incrementBy * cacheSize; byte[] valueBuffer = new byte[PDataType.LONG.getByteSize()]; PDataType.LONG.getCodec().encodeLong(value, valueBuffer, 0); Put put = new Put(row, currentValueKV.getTimestamp()); // Hold timestamp constant for sequences, so that clients always only see the latest value // regardless of when they connect. KeyValue newCurrentValueKV = KeyValueUtil.newKeyValue( row, currentValueKV.getFamily(), currentValueKV.getQualifier(), currentValueKV.getTimestamp(), valueBuffer); put.add(newCurrentValueKV); @SuppressWarnings("unchecked") Pair<Mutation, Integer>[] mutations = new Pair[1]; mutations[0] = new Pair<Mutation, Integer>(put, lid); region.batchMutate(mutations); return Sequence.replaceCurrentValueKV(result, newCurrentValueKV); } finally { region.releaseRowLock(lid); } } catch (Throwable t) { ServerUtil.throwIOException("Increment of sequence " + Bytes.toStringBinary(row), t); return null; // Impossible } finally { region.closeRegionOperation(); } }
/** * Override the preAppend for checkAndPut and checkAndDelete, as we need the ability to a) set the * TimeRange for the Get being done and b) return something back to the client to indicate * success/failure */ @SuppressWarnings("deprecation") @Override public Result preAppend( final ObserverContext<RegionCoprocessorEnvironment> e, final Append append) throws IOException { byte[] opBuf = append.getAttribute(OPERATION_ATTRIB); if (opBuf == null) { return null; } Op op = Op.values()[opBuf[0]]; long clientTimestamp = HConstants.LATEST_TIMESTAMP; byte[] clientTimestampBuf = append.getAttribute(MAX_TIMERANGE_ATTRIB); if (clientTimestampBuf != null) { clientTimestamp = Bytes.toLong(clientTimestampBuf); } boolean hadClientTimestamp = (clientTimestamp != HConstants.LATEST_TIMESTAMP); if (hadClientTimestamp) { // Prevent race condition of creating two sequences at the same timestamp // by looking for a sequence at or after the timestamp at which it'll be // created. if (op == Op.CREATE_SEQUENCE) { clientTimestamp++; } } else { clientTimestamp = EnvironmentEdgeManager.currentTimeMillis(); clientTimestampBuf = Bytes.toBytes(clientTimestamp); } RegionCoprocessorEnvironment env = e.getEnvironment(); // We need to set this to prevent region.append from being called e.bypass(); e.complete(); HRegion region = env.getRegion(); byte[] row = append.getRow(); region.startRegionOperation(); try { Integer lid = region.getLock(null, row, true); try { KeyValue keyValue = append.getFamilyMap().values().iterator().next().iterator().next(); byte[] family = keyValue.getFamily(); byte[] qualifier = keyValue.getQualifier(); Get get = new Get(row); get.setTimeRange(MetaDataProtocol.MIN_TABLE_TIMESTAMP, clientTimestamp); get.addColumn(family, qualifier); Result result = region.get(get); if (result.isEmpty()) { if (op == Op.DROP_SEQUENCE || op == Op.RESET_SEQUENCE) { return getErrorResult( row, clientTimestamp, SQLExceptionCode.SEQUENCE_UNDEFINED.getErrorCode()); } } else { if (op == Op.CREATE_SEQUENCE) { return getErrorResult( row, clientTimestamp, SQLExceptionCode.SEQUENCE_ALREADY_EXIST.getErrorCode()); } } Mutation m = null; switch (op) { case RESET_SEQUENCE: KeyValue currentValueKV = result.raw()[0]; long expectedValue = PDataType.LONG .getCodec() .decodeLong(append.getAttribute(CURRENT_VALUE_ATTRIB), 0, null); long value = PDataType.LONG .getCodec() .decodeLong(currentValueKV.getBuffer(), currentValueKV.getValueOffset(), null); // Timestamp should match exactly, or we may have the wrong sequence if (expectedValue != value || currentValueKV.getTimestamp() != clientTimestamp) { return new Result( Collections.singletonList( KeyValueUtil.newKeyValue( row, PhoenixDatabaseMetaData.SEQUENCE_FAMILY_BYTES, QueryConstants.EMPTY_COLUMN_BYTES, currentValueKV.getTimestamp(), ByteUtil.EMPTY_BYTE_ARRAY))); } m = new Put(row, currentValueKV.getTimestamp()); m.getFamilyMap().putAll(append.getFamilyMap()); break; case DROP_SEQUENCE: m = new Delete(row, clientTimestamp, null); break; case CREATE_SEQUENCE: m = new Put(row, clientTimestamp); m.getFamilyMap().putAll(append.getFamilyMap()); break; } if (!hadClientTimestamp) { for (List<KeyValue> kvs : m.getFamilyMap().values()) { for (KeyValue kv : kvs) { kv.updateLatestStamp(clientTimestampBuf); } } } @SuppressWarnings("unchecked") Pair<Mutation, Integer>[] mutations = new Pair[1]; mutations[0] = new Pair<Mutation, Integer>(m, lid); region.batchMutate(mutations); long serverTimestamp = MetaDataUtil.getClientTimeStamp(m); // Return result with single KeyValue. The only piece of information // the client cares about is the timestamp, which is the timestamp of // when the mutation was actually performed (useful in the case of . return new Result( Collections.singletonList( KeyValueUtil.newKeyValue( row, PhoenixDatabaseMetaData.SEQUENCE_FAMILY_BYTES, QueryConstants.EMPTY_COLUMN_BYTES, serverTimestamp, SUCCESS_VALUE))); } finally { region.releaseRowLock(lid); } } catch (Throwable t) { ServerUtil.throwIOException("Increment of sequence " + Bytes.toStringBinary(row), t); return null; // Impossible } finally { region.closeRegionOperation(); } }