/** Converts a call to an aggregate function to an expression. */
public SqlNode toSql(AggregateCall aggCall) {
SqlOperator op = (SqlAggFunction) aggCall.getAggregation();
final List<SqlNode> operands = Expressions.list();
for (int arg : aggCall.getArgList()) {
operands.add(field(arg));
}
return op.createCall(
aggCall.isDistinct() ? SqlSelectKeyword.DISTINCT.symbol(POS) : null,
POS,
operands.toArray(new SqlNode[operands.size()]));
}
private List<AggregateCall> transformAggCalls(
RelDataTypeFactory typeFactory, int nGroupCols, List<AggregateCall> origCalls) {
List<AggregateCall> newCalls = new ArrayList<AggregateCall>();
int iInput = nGroupCols;
for (AggregateCall origCall : origCalls) {
if (origCall.isDistinct()
|| !SUPPORTED_AGGREGATES.containsKey(origCall.getAggregation().getClass())) {
return null;
}
Aggregation aggFun;
RelDataType aggType;
if (origCall.getAggregation().getName().equals("COUNT")) {
aggFun = new SqlSumEmptyIsZeroAggFunction(origCall.getType());
SqlAggFunction af = (SqlAggFunction) aggFun;
final AggregateRelBase.AggCallBinding binding =
new AggregateRelBase.AggCallBinding(
typeFactory, af, Collections.singletonList(origCall.getType()), nGroupCols);
// count(any) is always not null, however nullability of sum might
// depend on the number of columns in GROUP BY.
// Here we use SUM0 since we are sure we will not face nullable
// inputs nor we'll face empty set.
aggType = af.inferReturnType(binding);
} else {
aggFun = origCall.getAggregation();
aggType = origCall.getType();
}
AggregateCall newCall =
new AggregateCall(
aggFun,
origCall.isDistinct(),
Collections.singletonList(iInput),
aggType,
origCall.getName());
newCalls.add(newCall);
++iInput;
}
return newCalls;
}
/** 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);
}
/** Generates the expression to retrieve the result of this aggregation. */
public Expression implementResult(AggregateCall call, Expression accumulator) {
OJAggImplementor aggImplementor = implementorTable.get(call.getAggregation());
return aggImplementor.implementResult(this, accumulator, call);
}
public void implementNext(AggregateCall call, JavaRel rel, Expression accumulator) {
OJAggImplementor aggImplementor = implementorTable.get(call.getAggregation());
aggImplementor.implementNext(this, rel, accumulator, call);
}
public Expression implementStartAndNext(AggregateCall call, JavaRel rel) {
OJAggImplementor aggImplementor = implementorTable.get(call.getAggregation());
return aggImplementor.implementStartAndNext(this, rel, call);
}
