예제 #1
0
 private static void setValues(
     byte[][] values,
     int[] pkSlotIndex,
     int[] columnIndexes,
     PTable table,
     Map<ImmutableBytesPtr, Map<PColumn, byte[]>> mutation) {
   Map<PColumn, byte[]> columnValues = Maps.newHashMapWithExpectedSize(columnIndexes.length);
   byte[][] pkValues = new byte[table.getPKColumns().size()][];
   // If the table uses salting, the first byte is the salting byte, set to an empty array
   // here and we will fill in the byte later in PRowImpl.
   if (table.getBucketNum() != null) {
     pkValues[0] = new byte[] {0};
   }
   for (int i = 0; i < values.length; i++) {
     byte[] value = values[i];
     PColumn column = table.getColumns().get(columnIndexes[i]);
     if (SchemaUtil.isPKColumn(column)) {
       pkValues[pkSlotIndex[i]] = value;
     } else {
       columnValues.put(column, value);
     }
   }
   ImmutableBytesPtr ptr = new ImmutableBytesPtr();
   table.newKey(ptr, pkValues);
   mutation.put(ptr, columnValues);
 }
예제 #2
0
 /**
  * Encode the primary key values from the table as a byte array. The values must be in the same
  * order as the primary key constraint. If the connection and table are both tenant-specific, the
  * tenant ID column must not be present in the values.
  *
  * @param conn an open connection
  * @param fullTableName the full table name
  * @param values the values of the primary key columns ordered in the same order as the primary
  *     key constraint
  * @return the encoded byte array
  * @throws SQLException if the table cannot be found or the incorrect number of of values are
  *     provided
  * @see #decodePK(Connection, String, byte[]) to decode the byte[] back to the values
  */
 public static byte[] encodePK(Connection conn, String fullTableName, Object[] values)
     throws SQLException {
   PTable table = getTable(conn, fullTableName);
   PhoenixConnection pconn = conn.unwrap(PhoenixConnection.class);
   int offset =
       (table.getBucketNum() == null ? 0 : 1)
           + (table.isMultiTenant() && pconn.getTenantId() != null ? 1 : 0);
   List<PColumn> pkColumns = table.getPKColumns();
   if (pkColumns.size() - offset != values.length) {
     throw new SQLException(
         "Expected " + (pkColumns.size() - offset) + " but got " + values.length);
   }
   PDataType type = null;
   TrustedByteArrayOutputStream output =
       new TrustedByteArrayOutputStream(table.getRowKeySchema().getEstimatedValueLength());
   try {
     for (int i = offset; i < pkColumns.size(); i++) {
       if (type != null && !type.isFixedWidth()) {
         output.write(QueryConstants.SEPARATOR_BYTE);
       }
       type = pkColumns.get(i).getDataType();
       byte[] value = type.toBytes(values[i - offset]);
       output.write(value);
     }
     return output.toByteArray();
   } finally {
     try {
       output.close();
     } catch (IOException e) {
       throw new RuntimeException(e); // Impossible
     }
   }
 }
예제 #3
0
 public static short getMaxKeySeq(PTable table) {
   int offset = 0;
   if (table.getBucketNum() != null) {
     offset++;
   }
   // TODO: for tenant-specific table on tenant-specific connection,
   // we should subtract one for tenant column and another one for
   // index ID
   return (short) (table.getPKColumns().size() - offset);
 }
예제 #4
0
 /**
  * Estimate the max key length in bytes of the PK for a given table
  *
  * @param table the table
  * @return the max PK length
  */
 public static int estimateKeyLength(PTable table) {
   int maxKeyLength = 0;
   // Calculate the max length of a key (each part must currently be of a fixed width)
   int i = 0;
   List<PColumn> columns = table.getPKColumns();
   while (i < columns.size()) {
     PColumn keyColumn = columns.get(i++);
     PDataType type = keyColumn.getDataType();
     Integer maxLength = keyColumn.getMaxLength();
     maxKeyLength +=
         !type.isFixedWidth()
             ? VAR_LENGTH_ESTIMATE
             : maxLength == null ? type.getByteSize() : maxLength;
   }
   return maxKeyLength;
 }
예제 #5
0
  public MutationPlan compile(UpsertStatement upsert) throws SQLException {
    final PhoenixConnection connection = statement.getConnection();
    ConnectionQueryServices services = connection.getQueryServices();
    final int maxSize =
        services
            .getProps()
            .getInt(
                QueryServices.MAX_MUTATION_SIZE_ATTRIB,
                QueryServicesOptions.DEFAULT_MAX_MUTATION_SIZE);
    final ColumnResolver resolver = FromCompiler.getResolverForMutation(upsert, connection);
    final TableRef tableRef = resolver.getTables().get(0);
    final PTable table = tableRef.getTable();
    if (table.getType() == PTableType.VIEW) {
      if (table.getViewType().isReadOnly()) {
        throw new ReadOnlyTableException(
            table.getSchemaName().getString(), table.getTableName().getString());
      }
    }
    boolean isSalted = table.getBucketNum() != null;
    final boolean isTenantSpecific = table.isMultiTenant() && connection.getTenantId() != null;
    final boolean isSharedViewIndex = table.getViewIndexId() != null;
    String tenantId = isTenantSpecific ? connection.getTenantId().getString() : null;
    int posOffset = isSalted ? 1 : 0;
    // Setup array of column indexes parallel to values that are going to be set
    List<ColumnName> columnNodes = upsert.getColumns();
    final List<PColumn> allColumns = table.getColumns();
    Set<PColumn> addViewColumnsToBe = Collections.emptySet();
    Set<PColumn> overlapViewColumnsToBe = Collections.emptySet();

    int[] columnIndexesToBe;
    int nColumnsToSet = 0;
    int[] pkSlotIndexesToBe;
    List<PColumn> targetColumns;
    if (table.getViewType() == ViewType.UPDATABLE) {
      addViewColumnsToBe = Sets.newLinkedHashSetWithExpectedSize(allColumns.size());
      for (PColumn column : allColumns) {
        if (column.getViewConstant() != null) {
          addViewColumnsToBe.add(column);
        }
      }
    }
    ImmutableBytesWritable ptr = new ImmutableBytesWritable();
    // Allow full row upsert if no columns or only dynamic ones are specified and values count match
    if (columnNodes.isEmpty()
        || columnNodes.size() == upsert.getTable().getDynamicColumns().size()) {
      nColumnsToSet = allColumns.size() - posOffset;
      columnIndexesToBe = new int[nColumnsToSet];
      pkSlotIndexesToBe = new int[columnIndexesToBe.length];
      targetColumns = Lists.newArrayListWithExpectedSize(columnIndexesToBe.length);
      targetColumns.addAll(Collections.<PColumn>nCopies(columnIndexesToBe.length, null));
      int minPKPos = 0;
      if (isTenantSpecific) {
        PColumn tenantColumn = table.getPKColumns().get(minPKPos);
        columnIndexesToBe[minPKPos] = tenantColumn.getPosition();
        targetColumns.set(minPKPos, tenantColumn);
        minPKPos++;
      }
      if (isSharedViewIndex) {
        PColumn indexIdColumn = table.getPKColumns().get(minPKPos);
        columnIndexesToBe[minPKPos] = indexIdColumn.getPosition();
        targetColumns.set(minPKPos, indexIdColumn);
        minPKPos++;
      }
      for (int i = posOffset, j = 0; i < allColumns.size(); i++) {
        PColumn column = allColumns.get(i);
        if (SchemaUtil.isPKColumn(column)) {
          pkSlotIndexesToBe[i - posOffset] = j + posOffset;
          if (j++ < minPKPos) { // Skip, as it's already been set above
            continue;
          }
          minPKPos = 0;
        }
        columnIndexesToBe[i - posOffset + minPKPos] = i;
        targetColumns.set(i - posOffset + minPKPos, column);
      }
      if (!addViewColumnsToBe.isEmpty()) {
        // All view columns overlap in this case
        overlapViewColumnsToBe = addViewColumnsToBe;
        addViewColumnsToBe = Collections.emptySet();
      }
    } else {
      // Size for worse case
      int numColsInUpsert = columnNodes.size();
      nColumnsToSet =
          numColsInUpsert
              + addViewColumnsToBe.size()
              + (isTenantSpecific ? 1 : 0)
              + +(isSharedViewIndex ? 1 : 0);
      columnIndexesToBe = new int[nColumnsToSet];
      pkSlotIndexesToBe = new int[columnIndexesToBe.length];
      targetColumns = Lists.newArrayListWithExpectedSize(columnIndexesToBe.length);
      targetColumns.addAll(Collections.<PColumn>nCopies(columnIndexesToBe.length, null));
      Arrays.fill(
          columnIndexesToBe,
          -1); // TODO: necessary? So we'll get an AIOB exception if it's not replaced
      Arrays.fill(
          pkSlotIndexesToBe,
          -1); // TODO: necessary? So we'll get an AIOB exception if it's not replaced
      BitSet pkColumnsSet = new BitSet(table.getPKColumns().size());
      int i = 0;
      // Add tenant column directly, as we don't want to resolve it as this will fail
      if (isTenantSpecific) {
        PColumn tenantColumn = table.getPKColumns().get(i + posOffset);
        columnIndexesToBe[i] = tenantColumn.getPosition();
        pkColumnsSet.set(pkSlotIndexesToBe[i] = i + posOffset);
        targetColumns.set(i, tenantColumn);
        i++;
      }
      if (isSharedViewIndex) {
        PColumn indexIdColumn = table.getPKColumns().get(i + posOffset);
        columnIndexesToBe[i] = indexIdColumn.getPosition();
        pkColumnsSet.set(pkSlotIndexesToBe[i] = i + posOffset);
        targetColumns.set(i, indexIdColumn);
        i++;
      }
      for (ColumnName colName : columnNodes) {
        ColumnRef ref =
            resolver.resolveColumn(null, colName.getFamilyName(), colName.getColumnName());
        PColumn column = ref.getColumn();
        if (IndexUtil.getViewConstantValue(column, ptr)) {
          if (overlapViewColumnsToBe.isEmpty()) {
            overlapViewColumnsToBe = Sets.newHashSetWithExpectedSize(addViewColumnsToBe.size());
          }
          nColumnsToSet--;
          overlapViewColumnsToBe.add(column);
          addViewColumnsToBe.remove(column);
        }
        columnIndexesToBe[i] = ref.getColumnPosition();
        targetColumns.set(i, column);
        if (SchemaUtil.isPKColumn(column)) {
          pkColumnsSet.set(pkSlotIndexesToBe[i] = ref.getPKSlotPosition());
        }
        i++;
      }
      for (PColumn column : addViewColumnsToBe) {
        columnIndexesToBe[i] = column.getPosition();
        targetColumns.set(i, column);
        if (SchemaUtil.isPKColumn(column)) {
          pkColumnsSet.set(pkSlotIndexesToBe[i] = SchemaUtil.getPKPosition(table, column));
        }
        i++;
      }
      for (i = posOffset; i < table.getPKColumns().size(); i++) {
        PColumn pkCol = table.getPKColumns().get(i);
        if (!pkColumnsSet.get(i)) {
          if (!pkCol.isNullable()) {
            throw new ConstraintViolationException(
                table.getName().getString()
                    + "."
                    + pkCol.getName().getString()
                    + " may not be null");
          }
        }
      }
    }

    List<ParseNode> valueNodes = upsert.getValues();
    QueryPlan plan = null;
    RowProjector rowProjectorToBe = null;
    final int nValuesToSet;
    boolean sameTable = false;
    boolean runOnServer = false;
    UpsertingParallelIteratorFactory upsertParallelIteratorFactoryToBe = null;
    final boolean isAutoCommit = connection.getAutoCommit();
    if (valueNodes == null) {
      SelectStatement select = upsert.getSelect();
      assert (select != null);
      select = SubselectRewriter.flatten(select, connection);
      ColumnResolver selectResolver = FromCompiler.getResolverForQuery(select, connection);
      select = StatementNormalizer.normalize(select, selectResolver);
      select = prependTenantAndViewConstants(table, select, tenantId, addViewColumnsToBe);
      sameTable =
          select.getFrom().size() == 1 && tableRef.equals(selectResolver.getTables().get(0));
      /* We can run the upsert in a coprocessor if:
       * 1) from has only 1 table and the into table matches from table
       * 2) the select query isn't doing aggregation
       * 3) autoCommit is on
       * 4) the table is not immutable, as the client is the one that figures out the additional
       *    puts for index tables.
       * 5) no limit clause
       * Otherwise, run the query to pull the data from the server
       * and populate the MutationState (upto a limit).
       */
      runOnServer =
          sameTable
              && isAutoCommit
              && !table.isImmutableRows()
              && !select.isAggregate()
              && !select.isDistinct()
              && select.getLimit() == null
              && table.getBucketNum() == null;
      ParallelIteratorFactory parallelIteratorFactory;
      if (select.isAggregate() || select.isDistinct() || select.getLimit() != null) {
        parallelIteratorFactory = null;
      } else {
        // We can pipeline the upsert select instead of spooling everything to disk first,
        // if we don't have any post processing that's required.
        parallelIteratorFactory =
            upsertParallelIteratorFactoryToBe =
                new UpsertingParallelIteratorFactory(connection, tableRef);
      }
      // If we may be able to run on the server, add a hint that favors using the data table
      // if all else is equal.
      // TODO: it'd be nice if we could figure out in advance if the PK is potentially changing,
      // as this would disallow running on the server. We currently use the row projector we
      // get back to figure this out.
      HintNode hint = upsert.getHint();
      if (!upsert.getHint().hasHint(Hint.USE_INDEX_OVER_DATA_TABLE)) {
        hint = HintNode.create(hint, Hint.USE_DATA_OVER_INDEX_TABLE);
      }
      select = SelectStatement.create(select, hint);
      // Pass scan through if same table in upsert and select so that projection is computed
      // correctly
      // Use optimizer to choose the best plan
      plan =
          new QueryOptimizer(services)
              .optimize(statement, select, selectResolver, targetColumns, parallelIteratorFactory);
      runOnServer &= plan.getTableRef().equals(tableRef);
      rowProjectorToBe = plan.getProjector();
      nValuesToSet = rowProjectorToBe.getColumnCount();
      // Cannot auto commit if doing aggregation or topN or salted
      // Salted causes problems because the row may end up living on a different region
    } else {
      nValuesToSet =
          valueNodes.size()
              + addViewColumnsToBe.size()
              + (isTenantSpecific ? 1 : 0)
              + (isSharedViewIndex ? 1 : 0);
    }
    final RowProjector projector = rowProjectorToBe;
    final UpsertingParallelIteratorFactory upsertParallelIteratorFactory =
        upsertParallelIteratorFactoryToBe;
    final QueryPlan queryPlan = plan;
    // Resize down to allow a subset of columns to be specifiable
    if (columnNodes.isEmpty() && columnIndexesToBe.length >= nValuesToSet) {
      nColumnsToSet = nValuesToSet;
      columnIndexesToBe = Arrays.copyOf(columnIndexesToBe, nValuesToSet);
      pkSlotIndexesToBe = Arrays.copyOf(pkSlotIndexesToBe, nValuesToSet);
    }

    if (nValuesToSet != nColumnsToSet) {
      throw new SQLExceptionInfo.Builder(SQLExceptionCode.UPSERT_COLUMN_NUMBERS_MISMATCH)
          .setMessage(
              "Numbers of columns: " + nColumnsToSet + ". Number of values: " + nValuesToSet)
          .build()
          .buildException();
    }

    final int[] columnIndexes = columnIndexesToBe;
    final int[] pkSlotIndexes = pkSlotIndexesToBe;
    final Set<PColumn> addViewColumns = addViewColumnsToBe;
    final Set<PColumn> overlapViewColumns = overlapViewColumnsToBe;

    // TODO: break this up into multiple functions
    ////////////////////////////////////////////////////////////////////
    // UPSERT SELECT
    /////////////////////////////////////////////////////////////////////
    if (valueNodes == null) {
      // Before we re-order, check that for updatable view columns
      // the projected expression either matches the column name or
      // is a constant with the same required value.
      throwIfNotUpdatable(tableRef, overlapViewColumnsToBe, targetColumns, projector, sameTable);

      ////////////////////////////////////////////////////////////////////
      // UPSERT SELECT run server-side (maybe)
      /////////////////////////////////////////////////////////////////////
      if (runOnServer) {
        // At most this array will grow bigger by the number of PK columns
        int[] allColumnsIndexes = Arrays.copyOf(columnIndexes, columnIndexes.length + nValuesToSet);
        int[] reverseColumnIndexes = new int[table.getColumns().size()];
        List<Expression> projectedExpressions =
            Lists.newArrayListWithExpectedSize(reverseColumnIndexes.length);
        Arrays.fill(reverseColumnIndexes, -1);
        for (int i = 0; i < nValuesToSet; i++) {
          projectedExpressions.add(projector.getColumnProjector(i).getExpression());
          reverseColumnIndexes[columnIndexes[i]] = i;
        }
        /*
         * Order projected columns and projected expressions with PK columns
         * leading order by slot position
         */
        int offset = table.getBucketNum() == null ? 0 : 1;
        for (int i = 0; i < table.getPKColumns().size() - offset; i++) {
          PColumn column = table.getPKColumns().get(i + offset);
          int pos = reverseColumnIndexes[column.getPosition()];
          if (pos == -1) {
            // Last PK column may be fixed width and nullable
            // We don't want to insert a null expression b/c
            // it's not valid to set a fixed width type to null.
            if (column.getDataType().isFixedWidth()) {
              continue;
            }
            // Add literal null for missing PK columns
            pos = projectedExpressions.size();
            Expression literalNull =
                LiteralExpression.newConstant(null, column.getDataType(), true);
            projectedExpressions.add(literalNull);
            allColumnsIndexes[pos] = column.getPosition();
          }
          // Swap select expression at pos with i
          Collections.swap(projectedExpressions, i, pos);
          // Swap column indexes and reverse column indexes too
          int tempPos = allColumnsIndexes[i];
          allColumnsIndexes[i] = allColumnsIndexes[pos];
          allColumnsIndexes[pos] = tempPos;
          reverseColumnIndexes[tempPos] = reverseColumnIndexes[i];
          reverseColumnIndexes[i] = i;
        }
        // If any pk slots are changing, be conservative and don't run this server side.
        // If the row ends up living in a different region, we'll get an error otherwise.
        for (int i = 0; i < table.getPKColumns().size(); i++) {
          PColumn column = table.getPKColumns().get(i);
          Expression source = projectedExpressions.get(i);
          if (source == null
              || !source.equals(
                  new ColumnRef(tableRef, column.getPosition()).newColumnExpression())) {
            // TODO: we could check the region boundaries to see if the pk will still be in it.
            runOnServer = false; // bail on running server side, since PK may be changing
            break;
          }
        }

        ////////////////////////////////////////////////////////////////////
        // UPSERT SELECT run server-side
        /////////////////////////////////////////////////////////////////////
        if (runOnServer) {
          // Iterate through columns being projected
          List<PColumn> projectedColumns =
              Lists.newArrayListWithExpectedSize(projectedExpressions.size());
          for (int i = 0; i < projectedExpressions.size(); i++) {
            // Must make new column if position has changed
            PColumn column = allColumns.get(allColumnsIndexes[i]);
            projectedColumns.add(column.getPosition() == i ? column : new PColumnImpl(column, i));
          }
          // Build table from projectedColumns
          PTable projectedTable = PTableImpl.makePTable(table, projectedColumns);

          SelectStatement select =
              SelectStatement.create(SelectStatement.COUNT_ONE, upsert.getHint());
          final RowProjector aggProjector =
              ProjectionCompiler.compile(queryPlan.getContext(), select, GroupBy.EMPTY_GROUP_BY);
          /*
           * Transfer over PTable representing subset of columns selected, but all PK columns.
           * Move columns setting PK first in pkSlot order, adding LiteralExpression of null for any missing ones.
           * Transfer over List<Expression> for projection.
           * In region scan, evaluate expressions in order, collecting first n columns for PK and collection non PK in mutation Map
           * Create the PRow and get the mutations, adding them to the batch
           */
          final StatementContext context = queryPlan.getContext();
          final Scan scan = context.getScan();
          scan.setAttribute(
              BaseScannerRegionObserver.UPSERT_SELECT_TABLE,
              UngroupedAggregateRegionObserver.serialize(projectedTable));
          scan.setAttribute(
              BaseScannerRegionObserver.UPSERT_SELECT_EXPRS,
              UngroupedAggregateRegionObserver.serialize(projectedExpressions));
          // Ignore order by - it has no impact
          final QueryPlan aggPlan =
              new AggregatePlan(
                  context,
                  select,
                  tableRef,
                  aggProjector,
                  null,
                  OrderBy.EMPTY_ORDER_BY,
                  null,
                  GroupBy.EMPTY_GROUP_BY,
                  null);
          return new MutationPlan() {

            @Override
            public PhoenixConnection getConnection() {
              return connection;
            }

            @Override
            public ParameterMetaData getParameterMetaData() {
              return queryPlan.getContext().getBindManager().getParameterMetaData();
            }

            @Override
            public StatementContext getContext() {
              return queryPlan.getContext();
            }

            @Override
            public MutationState execute() throws SQLException {
              ImmutableBytesWritable ptr = context.getTempPtr();
              tableRef.getTable().getIndexMaintainers(ptr);
              ServerCache cache = null;
              try {
                if (ptr.getLength() > 0) {
                  IndexMetaDataCacheClient client =
                      new IndexMetaDataCacheClient(connection, tableRef);
                  cache = client.addIndexMetadataCache(context.getScanRanges(), ptr);
                  byte[] uuidValue = cache.getId();
                  scan.setAttribute(PhoenixIndexCodec.INDEX_UUID, uuidValue);
                }
                ResultIterator iterator = aggPlan.iterator();
                try {
                  Tuple row = iterator.next();
                  final long mutationCount =
                      (Long) aggProjector.getColumnProjector(0).getValue(row, PDataType.LONG, ptr);
                  return new MutationState(maxSize, connection) {
                    @Override
                    public long getUpdateCount() {
                      return mutationCount;
                    }
                  };
                } finally {
                  iterator.close();
                }
              } finally {
                if (cache != null) {
                  cache.close();
                }
              }
            }

            @Override
            public ExplainPlan getExplainPlan() throws SQLException {
              List<String> queryPlanSteps = aggPlan.getExplainPlan().getPlanSteps();
              List<String> planSteps =
                  Lists.newArrayListWithExpectedSize(queryPlanSteps.size() + 1);
              planSteps.add("UPSERT ROWS");
              planSteps.addAll(queryPlanSteps);
              return new ExplainPlan(planSteps);
            }
          };
        }
      }

      ////////////////////////////////////////////////////////////////////
      // UPSERT SELECT run client-side
      /////////////////////////////////////////////////////////////////////
      return new MutationPlan() {

        @Override
        public PhoenixConnection getConnection() {
          return connection;
        }

        @Override
        public ParameterMetaData getParameterMetaData() {
          return queryPlan.getContext().getBindManager().getParameterMetaData();
        }

        @Override
        public StatementContext getContext() {
          return queryPlan.getContext();
        }

        @Override
        public MutationState execute() throws SQLException {
          ResultIterator iterator = queryPlan.iterator();
          if (upsertParallelIteratorFactory == null) {
            return upsertSelect(
                statement, tableRef, projector, iterator, columnIndexes, pkSlotIndexes);
          }
          upsertParallelIteratorFactory.setRowProjector(projector);
          upsertParallelIteratorFactory.setColumnIndexes(columnIndexes);
          upsertParallelIteratorFactory.setPkSlotIndexes(pkSlotIndexes);
          Tuple tuple;
          long totalRowCount = 0;
          while ((tuple = iterator.next()) != null) { // Runs query
            Cell kv = tuple.getValue(0);
            totalRowCount +=
                PDataType.LONG
                    .getCodec()
                    .decodeLong(kv.getValueArray(), kv.getValueOffset(), SortOrder.getDefault());
          }
          // Return total number of rows that have been updated. In the case of auto commit being
          // off
          // the mutations will all be in the mutation state of the current connection.
          return new MutationState(maxSize, statement.getConnection(), totalRowCount);
        }

        @Override
        public ExplainPlan getExplainPlan() throws SQLException {
          List<String> queryPlanSteps = queryPlan.getExplainPlan().getPlanSteps();
          List<String> planSteps = Lists.newArrayListWithExpectedSize(queryPlanSteps.size() + 1);
          planSteps.add("UPSERT SELECT");
          planSteps.addAll(queryPlanSteps);
          return new ExplainPlan(planSteps);
        }
      };
    }

    ////////////////////////////////////////////////////////////////////
    // UPSERT VALUES
    /////////////////////////////////////////////////////////////////////
    int nodeIndex = 0;
    // initialze values with constant byte values first
    final byte[][] values = new byte[nValuesToSet][];
    if (isTenantSpecific) {
      values[nodeIndex++] = connection.getTenantId().getBytes();
    }
    if (isSharedViewIndex) {
      values[nodeIndex++] = MetaDataUtil.getViewIndexIdDataType().toBytes(table.getViewIndexId());
    }
    final int nodeIndexOffset = nodeIndex;
    // Allocate array based on size of all columns in table,
    // since some values may not be set (if they're nullable).
    final StatementContext context = new StatementContext(statement, resolver, new Scan());
    UpsertValuesCompiler expressionBuilder = new UpsertValuesCompiler(context);
    final List<Expression> constantExpressions =
        Lists.newArrayListWithExpectedSize(valueNodes.size());
    // First build all the expressions, as with sequences we want to collect them all first
    // and initialize them in one batch
    for (ParseNode valueNode : valueNodes) {
      if (!valueNode.isStateless()) {
        throw new SQLExceptionInfo.Builder(SQLExceptionCode.VALUE_IN_UPSERT_NOT_CONSTANT)
            .build()
            .buildException();
      }
      PColumn column = allColumns.get(columnIndexes[nodeIndex]);
      expressionBuilder.setColumn(column);
      Expression expression = valueNode.accept(expressionBuilder);
      if (expression.getDataType() != null
          && !expression.getDataType().isCastableTo(column.getDataType())) {
        throw TypeMismatchException.newException(
            expression.getDataType(),
            column.getDataType(),
            "expression: " + expression.toString() + " in column " + column);
      }
      constantExpressions.add(expression);
      nodeIndex++;
    }
    return new MutationPlan() {

      @Override
      public PhoenixConnection getConnection() {
        return connection;
      }

      @Override
      public ParameterMetaData getParameterMetaData() {
        return context.getBindManager().getParameterMetaData();
      }

      @Override
      public StatementContext getContext() {
        return context;
      }

      @Override
      public MutationState execute() throws SQLException {
        ImmutableBytesWritable ptr = context.getTempPtr();
        final SequenceManager sequenceManager = context.getSequenceManager();
        // Next evaluate all the expressions
        int nodeIndex = nodeIndexOffset;
        Tuple tuple =
            sequenceManager.getSequenceCount() == 0 ? null : sequenceManager.newSequenceTuple(null);
        for (Expression constantExpression : constantExpressions) {
          PColumn column = allColumns.get(columnIndexes[nodeIndex]);
          constantExpression.evaluate(tuple, ptr);
          Object value = null;
          if (constantExpression.getDataType() != null) {
            value =
                constantExpression
                    .getDataType()
                    .toObject(
                        ptr,
                        constantExpression.getSortOrder(),
                        constantExpression.getMaxLength(),
                        constantExpression.getScale());
            if (!constantExpression.getDataType().isCoercibleTo(column.getDataType(), value)) {
              throw TypeMismatchException.newException(
                  constantExpression.getDataType(),
                  column.getDataType(),
                  "expression: " + constantExpression.toString() + " in column " + column);
            }
            if (!column
                .getDataType()
                .isSizeCompatible(
                    ptr,
                    value,
                    constantExpression.getDataType(),
                    constantExpression.getMaxLength(),
                    constantExpression.getScale(),
                    column.getMaxLength(),
                    column.getScale())) {
              throw new SQLExceptionInfo.Builder(SQLExceptionCode.DATA_EXCEEDS_MAX_CAPACITY)
                  .setColumnName(column.getName().getString())
                  .setMessage("value=" + constantExpression.toString())
                  .build()
                  .buildException();
            }
          }
          column
              .getDataType()
              .coerceBytes(
                  ptr,
                  value,
                  constantExpression.getDataType(),
                  constantExpression.getMaxLength(),
                  constantExpression.getScale(),
                  constantExpression.getSortOrder(),
                  column.getMaxLength(),
                  column.getScale(),
                  column.getSortOrder());
          if (overlapViewColumns.contains(column)
              && Bytes.compareTo(
                      ptr.get(),
                      ptr.getOffset(),
                      ptr.getLength(),
                      column.getViewConstant(),
                      0,
                      column.getViewConstant().length - 1)
                  != 0) {
            throw new SQLExceptionInfo.Builder(SQLExceptionCode.CANNOT_UPDATE_VIEW_COLUMN)
                .setColumnName(column.getName().getString())
                .setMessage("value=" + constantExpression.toString())
                .build()
                .buildException();
          }
          values[nodeIndex] = ByteUtil.copyKeyBytesIfNecessary(ptr);
          nodeIndex++;
        }
        // Add columns based on view
        for (PColumn column : addViewColumns) {
          if (IndexUtil.getViewConstantValue(column, ptr)) {
            values[nodeIndex++] = ByteUtil.copyKeyBytesIfNecessary(ptr);
          } else {
            throw new IllegalStateException();
          }
        }
        Map<ImmutableBytesPtr, Map<PColumn, byte[]>> mutation = Maps.newHashMapWithExpectedSize(1);
        setValues(values, pkSlotIndexes, columnIndexes, tableRef.getTable(), mutation);
        return new MutationState(tableRef, mutation, 0, maxSize, connection);
      }

      @Override
      public ExplainPlan getExplainPlan() throws SQLException {
        List<String> planSteps = Lists.newArrayListWithExpectedSize(2);
        if (context.getSequenceManager().getSequenceCount() > 0) {
          planSteps.add(
              "CLIENT RESERVE " + context.getSequenceManager().getSequenceCount() + " SEQUENCES");
        }
        planSteps.add("PUT SINGLE ROW");
        return new ExplainPlan(planSteps);
      }
    };
  }
예제 #6
0
 public static int getPKPosition(PTable table, PColumn column) {
   // TODO: when PColumn has getPKPosition, use that instead
   return table.getPKColumns().indexOf(column);
 }
예제 #7
0
  private static QueryPlan addPlan(
      PhoenixStatement statement,
      SelectStatement select,
      PTable index,
      List<? extends PDatum> targetColumns,
      ParallelIteratorFactory parallelIteratorFactory,
      QueryPlan dataPlan,
      boolean isHinted)
      throws SQLException {
    int nColumns = dataPlan.getProjector().getColumnCount();
    String tableAlias = dataPlan.getTableRef().getTableAlias();
    String alias =
        tableAlias == null
            ? null
            : '"' + tableAlias + '"'; // double quote in case it's case sensitive
    String schemaName = index.getParentSchemaName().getString();
    schemaName = schemaName.length() == 0 ? null : '"' + schemaName + '"';

    String tableName = '"' + index.getTableName().getString() + '"';
    TableNode table = FACTORY.namedTable(alias, FACTORY.table(schemaName, tableName));
    SelectStatement indexSelect = FACTORY.select(select, table);
    ColumnResolver resolver =
        FromCompiler.getResolverForQuery(indexSelect, statement.getConnection());
    // We will or will not do tuple projection according to the data plan.
    boolean isProjected =
        dataPlan.getContext().getResolver().getTables().get(0).getTable().getType()
            == PTableType.PROJECTED;
    // Check index state of now potentially updated index table to make sure it's active
    if (PIndexState.ACTIVE.equals(resolver.getTables().get(0).getTable().getIndexState())) {
      try {
        // translate nodes that match expressions that are indexed to the associated column parse
        // node
        indexSelect =
            ParseNodeRewriter.rewrite(
                indexSelect,
                new IndexExpressionParseNodeRewriter(
                    index, statement.getConnection(), indexSelect.getUdfParseNodes()));
        QueryCompiler compiler =
            new QueryCompiler(
                statement,
                indexSelect,
                resolver,
                targetColumns,
                parallelIteratorFactory,
                dataPlan.getContext().getSequenceManager(),
                isProjected);

        QueryPlan plan = compiler.compile();
        // If query doesn't have where clause and some of columns to project are missing
        // in the index then we need to get missing columns from main table for each row in
        // local index. It's like full scan of both local index and data table which is inefficient.
        // Then we don't use the index. If all the columns to project are present in the index
        // then we can use the index even the query doesn't have where clause.
        if (index.getIndexType() == IndexType.LOCAL
            && indexSelect.getWhere() == null
            && !plan.getContext().getDataColumns().isEmpty()) {
          return null;
        }
        // Checking number of columns handles the wildcard cases correctly, as in that case the
        // index
        // must contain all columns from the data table to be able to be used.
        if (plan.getTableRef().getTable().getIndexState() == PIndexState.ACTIVE) {
          if (plan.getProjector().getColumnCount() == nColumns) {
            return plan;
          } else if (index.getIndexType() == IndexType.GLOBAL) {
            throw new ColumnNotFoundException("*");
          }
        }
      } catch (ColumnNotFoundException e) {
        /* Means that a column is being used that's not in our index.
         * Since we currently don't keep stats, we don't know the selectivity of the index.
         * For now, if this is a hinted plan, we will try rewriting the query as a subquery;
         * otherwise we just don't use this index (as opposed to trying to join back from
         * the index table to the data table.
         */
        SelectStatement dataSelect = (SelectStatement) dataPlan.getStatement();
        ParseNode where = dataSelect.getWhere();
        if (isHinted && where != null) {
          StatementContext context = new StatementContext(statement, resolver);
          WhereConditionRewriter whereRewriter =
              new WhereConditionRewriter(FromCompiler.getResolver(dataPlan.getTableRef()), context);
          where = where.accept(whereRewriter);
          if (where != null) {
            PTable dataTable = dataPlan.getTableRef().getTable();
            List<PColumn> pkColumns = dataTable.getPKColumns();
            List<AliasedNode> aliasedNodes =
                Lists.<AliasedNode>newArrayListWithExpectedSize(pkColumns.size());
            List<ParseNode> nodes = Lists.<ParseNode>newArrayListWithExpectedSize(pkColumns.size());
            boolean isSalted = dataTable.getBucketNum() != null;
            boolean isTenantSpecific =
                dataTable.isMultiTenant() && statement.getConnection().getTenantId() != null;
            int posOffset = (isSalted ? 1 : 0) + (isTenantSpecific ? 1 : 0);
            for (int i = posOffset; i < pkColumns.size(); i++) {
              PColumn column = pkColumns.get(i);
              String indexColName = IndexUtil.getIndexColumnName(column);
              ParseNode indexColNode =
                  new ColumnParseNode(null, '"' + indexColName + '"', indexColName);
              PDataType indexColType = IndexUtil.getIndexColumnDataType(column);
              PDataType dataColType = column.getDataType();
              if (indexColType != dataColType) {
                indexColNode = FACTORY.cast(indexColNode, dataColType, null, null);
              }
              aliasedNodes.add(FACTORY.aliasedNode(null, indexColNode));
              nodes.add(new ColumnParseNode(null, '"' + column.getName().getString() + '"'));
            }
            SelectStatement innerSelect =
                FACTORY.select(
                    indexSelect.getFrom(),
                    indexSelect.getHint(),
                    false,
                    aliasedNodes,
                    where,
                    null,
                    null,
                    null,
                    null,
                    null,
                    indexSelect.getBindCount(),
                    false,
                    indexSelect.hasSequence(),
                    Collections.<SelectStatement>emptyList(),
                    indexSelect.getUdfParseNodes());
            ParseNode outerWhere =
                FACTORY.in(
                    nodes.size() == 1 ? nodes.get(0) : FACTORY.rowValueConstructor(nodes),
                    FACTORY.subquery(innerSelect, false),
                    false,
                    true);
            ParseNode extractedCondition = whereRewriter.getExtractedCondition();
            if (extractedCondition != null) {
              outerWhere = FACTORY.and(Lists.newArrayList(outerWhere, extractedCondition));
            }
            HintNode hint =
                HintNode.combine(
                    HintNode.subtract(
                        indexSelect.getHint(),
                        new Hint[] {Hint.INDEX, Hint.NO_CHILD_PARENT_JOIN_OPTIMIZATION}),
                    FACTORY.hint("NO_INDEX"));
            SelectStatement query = FACTORY.select(dataSelect, hint, outerWhere);
            ColumnResolver queryResolver =
                FromCompiler.getResolverForQuery(query, statement.getConnection());
            query = SubqueryRewriter.transform(query, queryResolver, statement.getConnection());
            queryResolver = FromCompiler.getResolverForQuery(query, statement.getConnection());
            query = StatementNormalizer.normalize(query, queryResolver);
            QueryPlan plan =
                new QueryCompiler(
                        statement,
                        query,
                        queryResolver,
                        targetColumns,
                        parallelIteratorFactory,
                        dataPlan.getContext().getSequenceManager(),
                        isProjected)
                    .compile();
            return plan;
          }
        }
      }
    }
    return null;
  }
  @Override
  protected RegionScanner doPostScannerOpen(
      final ObserverContext<RegionCoprocessorEnvironment> c, final Scan scan, final RegionScanner s)
      throws IOException {
    byte[] isUngroupedAgg = scan.getAttribute(BaseScannerRegionObserver.UNGROUPED_AGG);
    if (isUngroupedAgg == null) {
      return s;
    }

    final ScanProjector p = ScanProjector.deserializeProjectorFromScan(scan);
    final HashJoinInfo j = HashJoinInfo.deserializeHashJoinFromScan(scan);
    RegionScanner theScanner = s;
    if (p != null || j != null) {
      theScanner =
          new HashJoinRegionScanner(s, p, j, ScanUtil.getTenantId(scan), c.getEnvironment());
    }
    final RegionScanner innerScanner = theScanner;

    byte[] indexUUID = scan.getAttribute(PhoenixIndexCodec.INDEX_UUID);
    PTable projectedTable = null;
    List<Expression> selectExpressions = null;
    byte[] upsertSelectTable = scan.getAttribute(BaseScannerRegionObserver.UPSERT_SELECT_TABLE);
    boolean isUpsert = false;
    boolean isDelete = false;
    byte[] deleteCQ = null;
    byte[] deleteCF = null;
    byte[][] values = null;
    byte[] emptyCF = null;
    ImmutableBytesWritable ptr = null;
    if (upsertSelectTable != null) {
      isUpsert = true;
      projectedTable = deserializeTable(upsertSelectTable);
      selectExpressions =
          deserializeExpressions(scan.getAttribute(BaseScannerRegionObserver.UPSERT_SELECT_EXPRS));
      values = new byte[projectedTable.getPKColumns().size()][];
      ptr = new ImmutableBytesWritable();
    } else {
      byte[] isDeleteAgg = scan.getAttribute(BaseScannerRegionObserver.DELETE_AGG);
      isDelete = isDeleteAgg != null && Bytes.compareTo(PDataType.TRUE_BYTES, isDeleteAgg) == 0;
      if (!isDelete) {
        deleteCF = scan.getAttribute(BaseScannerRegionObserver.DELETE_CF);
        deleteCQ = scan.getAttribute(BaseScannerRegionObserver.DELETE_CQ);
      }
      emptyCF = scan.getAttribute(BaseScannerRegionObserver.EMPTY_CF);
    }

    int batchSize = 0;
    long ts = scan.getTimeRange().getMax();
    HRegion region = c.getEnvironment().getRegion();
    List<Mutation> mutations = Collections.emptyList();
    if (isDelete || isUpsert || (deleteCQ != null && deleteCF != null) || emptyCF != null) {
      // TODO: size better
      mutations = Lists.newArrayListWithExpectedSize(1024);
      batchSize =
          c.getEnvironment()
              .getConfiguration()
              .getInt(MUTATE_BATCH_SIZE_ATTRIB, QueryServicesOptions.DEFAULT_MUTATE_BATCH_SIZE);
    }
    Aggregators aggregators =
        ServerAggregators.deserialize(
            scan.getAttribute(BaseScannerRegionObserver.AGGREGATORS),
            c.getEnvironment().getConfiguration());
    Aggregator[] rowAggregators = aggregators.getAggregators();
    boolean hasMore;
    boolean hasAny = false;
    MultiKeyValueTuple result = new MultiKeyValueTuple();
    if (logger.isInfoEnabled()) {
      logger.info("Starting ungrouped coprocessor scan " + scan);
    }
    long rowCount = 0;
    region.startRegionOperation();
    try {
      do {
        List<Cell> results = new ArrayList<Cell>();
        // Results are potentially returned even when the return value of s.next is false
        // since this is an indication of whether or not there are more values after the
        // ones returned
        hasMore = innerScanner.nextRaw(results);
        if (!results.isEmpty()) {
          rowCount++;
          result.setKeyValues(results);
          try {
            if (isDelete) {
              // FIXME: the version of the Delete constructor without the lock args was introduced
              // in 0.94.4, thus if we try to use it here we can no longer use the 0.94.2 version
              // of the client.
              Cell firstKV = results.get(0);
              Delete delete =
                  new Delete(
                      firstKV.getRowArray(), firstKV.getRowOffset(), firstKV.getRowLength(), ts);
              mutations.add(delete);
            } else if (isUpsert) {
              Arrays.fill(values, null);
              int i = 0;
              List<PColumn> projectedColumns = projectedTable.getColumns();
              for (; i < projectedTable.getPKColumns().size(); i++) {
                Expression expression = selectExpressions.get(i);
                if (expression.evaluate(result, ptr)) {
                  values[i] = ptr.copyBytes();
                  // If SortOrder from expression in SELECT doesn't match the
                  // column being projected into then invert the bits.
                  if (expression.getSortOrder() != projectedColumns.get(i).getSortOrder()) {
                    SortOrder.invert(values[i], 0, values[i], 0, values[i].length);
                  }
                }
              }
              projectedTable.newKey(ptr, values);
              PRow row = projectedTable.newRow(kvBuilder, ts, ptr);
              for (; i < projectedColumns.size(); i++) {
                Expression expression = selectExpressions.get(i);
                if (expression.evaluate(result, ptr)) {
                  PColumn column = projectedColumns.get(i);
                  Object value = expression.getDataType().toObject(ptr, column.getSortOrder());
                  // We are guaranteed that the two column will have the same type.
                  if (!column
                      .getDataType()
                      .isSizeCompatible(
                          ptr,
                          value,
                          column.getDataType(),
                          expression.getMaxLength(),
                          expression.getScale(),
                          column.getMaxLength(),
                          column.getScale())) {
                    throw new ValueTypeIncompatibleException(
                        column.getDataType(), column.getMaxLength(), column.getScale());
                  }
                  column
                      .getDataType()
                      .coerceBytes(
                          ptr,
                          value,
                          expression.getDataType(),
                          expression.getMaxLength(),
                          expression.getScale(),
                          expression.getSortOrder(),
                          column.getMaxLength(),
                          column.getScale(),
                          column.getSortOrder());
                  byte[] bytes = ByteUtil.copyKeyBytesIfNecessary(ptr);
                  row.setValue(column, bytes);
                }
              }
              for (Mutation mutation : row.toRowMutations()) {
                mutations.add(mutation);
              }
            } else if (deleteCF != null && deleteCQ != null) {
              // No need to search for delete column, since we project only it
              // if no empty key value is being set
              if (emptyCF == null || result.getValue(deleteCF, deleteCQ) != null) {
                Delete delete =
                    new Delete(
                        results.get(0).getRowArray(),
                        results.get(0).getRowOffset(),
                        results.get(0).getRowLength());
                delete.deleteColumns(deleteCF, deleteCQ, ts);
                mutations.add(delete);
              }
            }
            if (emptyCF != null) {
              /*
               * If we've specified an emptyCF, then we need to insert an empty
               * key value "retroactively" for any key value that is visible at
               * the timestamp that the DDL was issued. Key values that are not
               * visible at this timestamp will not ever be projected up to
               * scans past this timestamp, so don't need to be considered.
               * We insert one empty key value per row per timestamp.
               */
              Set<Long> timeStamps = Sets.newHashSetWithExpectedSize(results.size());
              for (Cell kv : results) {
                long kvts = kv.getTimestamp();
                if (!timeStamps.contains(kvts)) {
                  Put put = new Put(kv.getRowArray(), kv.getRowOffset(), kv.getRowLength());
                  put.add(
                      emptyCF, QueryConstants.EMPTY_COLUMN_BYTES, kvts, ByteUtil.EMPTY_BYTE_ARRAY);
                  mutations.add(put);
                }
              }
            }
            // Commit in batches based on UPSERT_BATCH_SIZE_ATTRIB in config
            if (!mutations.isEmpty() && batchSize > 0 && mutations.size() % batchSize == 0) {
              commitBatch(region, mutations, indexUUID);
              mutations.clear();
            }
          } catch (ConstraintViolationException e) {
            // Log and ignore in count
            logger.error(
                "Failed to create row in "
                    + region.getRegionNameAsString()
                    + " with values "
                    + SchemaUtil.toString(values),
                e);
            continue;
          }
          aggregators.aggregate(rowAggregators, result);
          hasAny = true;
        }
      } while (hasMore);
    } finally {
      innerScanner.close();
      region.closeRegionOperation();
    }

    if (logger.isInfoEnabled()) {
      logger.info("Finished scanning " + rowCount + " rows for ungrouped coprocessor scan " + scan);
    }

    if (!mutations.isEmpty()) {
      commitBatch(region, mutations, indexUUID);
    }

    final boolean hadAny = hasAny;
    KeyValue keyValue = null;
    if (hadAny) {
      byte[] value = aggregators.toBytes(rowAggregators);
      keyValue =
          KeyValueUtil.newKeyValue(
              UNGROUPED_AGG_ROW_KEY,
              SINGLE_COLUMN_FAMILY,
              SINGLE_COLUMN,
              AGG_TIMESTAMP,
              value,
              0,
              value.length);
    }
    final KeyValue aggKeyValue = keyValue;

    RegionScanner scanner =
        new BaseRegionScanner() {
          private boolean done = !hadAny;

          @Override
          public HRegionInfo getRegionInfo() {
            return innerScanner.getRegionInfo();
          }

          @Override
          public boolean isFilterDone() {
            return done;
          }

          @Override
          public void close() throws IOException {
            innerScanner.close();
          }

          @Override
          public boolean next(List<Cell> results) throws IOException {
            if (done) return false;
            done = true;
            results.add(aggKeyValue);
            return false;
          }

          @Override
          public long getMaxResultSize() {
            return scan.getMaxResultSize();
          }
        };
    return scanner;
  }