/** Variant of {@link #trimFields(RelNode, BitSet, Set)} for {@link TableFunctionRel}. */ public TrimResult trimFields( TableFunctionRel tabFun, BitSet fieldsUsed, Set<RelDataTypeField> extraFields) { final RelDataType rowType = tabFun.getRowType(); final int fieldCount = rowType.getFieldCount(); List<RelNode> newInputs = new ArrayList<RelNode>(); for (RelNode input : tabFun.getInputs()) { final int inputFieldCount = input.getRowType().getFieldCount(); BitSet inputFieldsUsed = Util.bitSetBetween(0, inputFieldCount); // Create input with trimmed columns. final Set<RelDataTypeField> inputExtraFields = Collections.emptySet(); TrimResult trimResult = trimChildRestore(tabFun, input, inputFieldsUsed, inputExtraFields); assert trimResult.right.isIdentity(); newInputs.add(trimResult.left); } TableFunctionRel newTabFun = tabFun; if (!tabFun.getInputs().equals(newInputs)) { newTabFun = tabFun.copy(tabFun.getTraitSet(), newInputs); } assert newTabFun.getClass() == tabFun.getClass(); // Always project all fields. Mapping mapping = Mappings.createIdentity(fieldCount); return new TrimResult(newTabFun, mapping); }
/** Variant of {@link #trimFields(RelNode, BitSet, Set)} for {@link TableModificationRel}. */ public TrimResult trimFields( TableModificationRel modifier, BitSet fieldsUsed, Set<RelDataTypeField> extraFields) { // Ignore what consumer wants. We always project all columns. Util.discard(fieldsUsed); final RelDataType rowType = modifier.getRowType(); final int fieldCount = rowType.getFieldCount(); RelNode input = modifier.getChild(); // We want all fields from the child. final int inputFieldCount = input.getRowType().getFieldCount(); BitSet inputFieldsUsed = Util.bitSetBetween(0, inputFieldCount); // Create input with trimmed columns. final Set<RelDataTypeField> inputExtraFields = Collections.emptySet(); TrimResult trimResult = trimChild(modifier, input, inputFieldsUsed, inputExtraFields); RelNode newInput = trimResult.left; final Mapping inputMapping = trimResult.right; if (!inputMapping.isIdentity()) { // We asked for all fields. Can't believe that the child decided // to permute them! throw Util.newInternal("Expected identity mapping, got " + inputMapping); } TableModificationRel newModifier = modifier; if (newInput != input) { newModifier = modifier.copy(modifier.getTraitSet(), Collections.singletonList(newInput)); } assert newModifier.getClass() == modifier.getClass(); // Always project all fields. Mapping mapping = Mappings.createIdentity(fieldCount); return new TrimResult(newModifier, mapping); }
/** Variant of {@link #trimFields(RelNode, BitSet, Set)} for {@link SortRel}. */ public TrimResult trimFields(SortRel sort, BitSet fieldsUsed, Set<RelDataTypeField> extraFields) { final RelDataType rowType = sort.getRowType(); final int fieldCount = rowType.getFieldCount(); final RelCollation collation = sort.getCollation(); final RelNode input = sort.getChild(); // We use the fields used by the consumer, plus any fields used as sort // keys. BitSet inputFieldsUsed = (BitSet) fieldsUsed.clone(); for (RelFieldCollation field : collation.getFieldCollations()) { inputFieldsUsed.set(field.getFieldIndex()); } // Create input with trimmed columns. final Set<RelDataTypeField> inputExtraFields = Collections.emptySet(); TrimResult trimResult = trimChild(sort, input, inputFieldsUsed, inputExtraFields); RelNode newInput = trimResult.left; final Mapping inputMapping = trimResult.right; // If the input is unchanged, and we need to project all columns, // there's nothing we can do. if (newInput == input && inputMapping.isIdentity() && fieldsUsed.cardinality() == fieldCount) { return new TrimResult(sort, Mappings.createIdentity(fieldCount)); } final SortRel newSort = sort.copy(sort.getTraitSet(), newInput, RexUtil.apply(inputMapping, collation)); assert newSort.getClass() == sort.getClass(); // The result has the same mapping as the input gave us. Sometimes we // return fields that the consumer didn't ask for, because the filter // needs them for its condition. return new TrimResult(newSort, inputMapping); }
/** * Trims unused fields from a relational expression. * * <p>We presume that all fields of the relational expression are wanted by its consumer, so only * trim fields that are not used within the tree. * * @param root Root node of relational expression * @return Trimmed relational expression */ public RelNode trim(RelNode root) { final int fieldCount = root.getRowType().getFieldCount(); final BitSet fieldsUsed = Util.bitSetBetween(0, fieldCount); final Set<RelDataTypeField> extraFields = Collections.emptySet(); final TrimResult trimResult = dispatchTrimFields(root, fieldsUsed, extraFields); if (!trimResult.right.isIdentity()) { throw new IllegalArgumentException(); } return trimResult.left; }
/** Variant of {@link #trimFields(RelNode, BitSet, Set)} for {@link AggregateRel}. */ public TrimResult trimFields( AggregateRel aggregate, BitSet fieldsUsed, Set<RelDataTypeField> extraFields) { // Fields: // // | sys fields | group fields | agg functions | // // Two kinds of trimming: // // 1. If agg rel has system fields but none of these are used, create an // agg rel with no system fields. // // 2. If aggregate functions are not used, remove them. // // But grouping fields stay, even if they are not used. final RelDataType rowType = aggregate.getRowType(); // Compute which input fields are used. BitSet inputFieldsUsed = new BitSet(); // 1. group fields are always used for (int i : Util.toIter(aggregate.getGroupSet())) { inputFieldsUsed.set(i); } // 2. agg functions for (AggregateCall aggCall : aggregate.getAggCallList()) { for (int i : aggCall.getArgList()) { inputFieldsUsed.set(i); } } // Create input with trimmed columns. final RelNode input = aggregate.getInput(0); final Set<RelDataTypeField> inputExtraFields = Collections.emptySet(); final TrimResult trimResult = trimChild(aggregate, input, inputFieldsUsed, inputExtraFields); final RelNode newInput = trimResult.left; final Mapping inputMapping = trimResult.right; // If the input is unchanged, and we need to project all columns, // there's nothing to do. if (input == newInput && fieldsUsed.equals(Util.bitSetBetween(0, rowType.getFieldCount()))) { return new TrimResult(aggregate, Mappings.createIdentity(rowType.getFieldCount())); } // Which agg calls are used by our consumer? final int groupCount = aggregate.getGroupSet().cardinality(); int j = groupCount; int usedAggCallCount = 0; for (int i = 0; i < aggregate.getAggCallList().size(); i++) { if (fieldsUsed.get(j++)) { ++usedAggCallCount; } } // Offset due to the number of system fields having changed. Mapping mapping = Mappings.create( MappingType.InverseSurjection, rowType.getFieldCount(), groupCount + usedAggCallCount); final BitSet newGroupSet = Mappings.apply(inputMapping, aggregate.getGroupSet()); // Populate mapping of where to find the fields. System and grouping // fields first. for (IntPair pair : inputMapping) { if (pair.source < groupCount) { mapping.set(pair.source, pair.target); } } // Now create new agg calls, and populate mapping for them. final List<AggregateCall> newAggCallList = new ArrayList<AggregateCall>(); j = groupCount; for (AggregateCall aggCall : aggregate.getAggCallList()) { if (fieldsUsed.get(j)) { AggregateCall newAggCall = new AggregateCall( aggCall.getAggregation(), aggCall.isDistinct(), Mappings.apply2(inputMapping, aggCall.getArgList()), aggCall.getType(), aggCall.getName()); if (newAggCall.equals(aggCall)) { newAggCall = aggCall; // immutable -> canonize to save space } mapping.set(j, groupCount + newAggCallList.size()); newAggCallList.add(newAggCall); } ++j; } RelNode newAggregate = new AggregateRel(aggregate.getCluster(), newInput, newGroupSet, newAggCallList); assert newAggregate.getClass() == aggregate.getClass(); return new TrimResult(newAggregate, mapping); }
/** Variant of {@link #trimFields(RelNode, BitSet, Set)} for {@link JoinRel}. */ public TrimResult trimFields(JoinRel join, BitSet fieldsUsed, Set<RelDataTypeField> extraFields) { final RelDataType rowType = join.getRowType(); final int fieldCount = rowType.getFieldCount(); final RexNode conditionExpr = join.getCondition(); final int systemFieldCount = join.getSystemFieldList().size(); // Add in fields used in the condition. BitSet fieldsUsedPlus = (BitSet) fieldsUsed.clone(); final Set<RelDataTypeField> combinedInputExtraFields = new LinkedHashSet<RelDataTypeField>(extraFields); RelOptUtil.InputFinder inputFinder = new RelOptUtil.InputFinder(fieldsUsedPlus, combinedInputExtraFields); conditionExpr.accept(inputFinder); // If no system fields are used, we can remove them. int systemFieldUsedCount = 0; for (int i = 0; i < systemFieldCount; ++i) { if (fieldsUsed.get(i)) { ++systemFieldUsedCount; } } final int newSystemFieldCount; if (systemFieldUsedCount == 0) { newSystemFieldCount = 0; } else { newSystemFieldCount = systemFieldCount; } int offset = systemFieldCount; int changeCount = 0; int newFieldCount = newSystemFieldCount; List<RelNode> newInputs = new ArrayList<RelNode>(2); List<Mapping> inputMappings = new ArrayList<Mapping>(); List<Integer> inputExtraFieldCounts = new ArrayList<Integer>(); for (RelNode input : join.getInputs()) { final RelDataType inputRowType = input.getRowType(); final int inputFieldCount = inputRowType.getFieldCount(); // Compute required mapping. BitSet inputFieldsUsed = new BitSet(inputFieldCount); for (int bit : Util.toIter(fieldsUsedPlus)) { if (bit >= offset && bit < offset + inputFieldCount) { inputFieldsUsed.set(bit - offset); } } // If there are system fields, we automatically use the // corresponding field in each input. if (newSystemFieldCount > 0) { // calling with newSystemFieldCount == 0 should be safe but hits // http://bugs.sun.com/bugdatabase/view_bug.do?bug_id=6222207 inputFieldsUsed.set(0, newSystemFieldCount); } // FIXME: We ought to collect extra fields for each input // individually. For now, we assume that just one input has // on-demand fields. Set<RelDataTypeField> inputExtraFields = input.getRowType().getField("_extra") == null ? Collections.<RelDataTypeField>emptySet() : combinedInputExtraFields; inputExtraFieldCounts.add(inputExtraFields.size()); TrimResult trimResult = trimChild(join, input, inputFieldsUsed, inputExtraFields); newInputs.add(trimResult.left); if (trimResult.left != input) { ++changeCount; } final Mapping inputMapping = trimResult.right; inputMappings.add(inputMapping); // Move offset to point to start of next input. offset += inputFieldCount; newFieldCount += inputMapping.getTargetCount() + inputExtraFields.size(); } Mapping mapping = Mappings.create(MappingType.InverseSurjection, fieldCount, newFieldCount); for (int i = 0; i < newSystemFieldCount; ++i) { mapping.set(i, i); } offset = systemFieldCount; int newOffset = newSystemFieldCount; for (int i = 0; i < inputMappings.size(); i++) { Mapping inputMapping = inputMappings.get(i); for (IntPair pair : inputMapping) { mapping.set(pair.source + offset, pair.target + newOffset); } offset += inputMapping.getSourceCount(); newOffset += inputMapping.getTargetCount() + inputExtraFieldCounts.get(i); } if (changeCount == 0 && mapping.isIdentity()) { return new TrimResult(join, Mappings.createIdentity(fieldCount)); } // Build new join. final RexVisitor<RexNode> shuttle = new RexPermuteInputsShuttle(mapping, newInputs.get(0), newInputs.get(1)); RexNode newConditionExpr = conditionExpr.accept(shuttle); final JoinRel newJoin = join.copy(join.getTraitSet(), newConditionExpr, newInputs.get(0), newInputs.get(1)); return new TrimResult(newJoin, mapping); }