Exemple #1
0
TupleSchema* AbstractPlanNode::generateTupleSchema(const std::vector<SchemaColumn*>& outputSchema)
{
    int schema_size = static_cast<int>(outputSchema.size());
    vector<voltdb::ValueType> columnTypes;
    vector<int32_t> columnSizes;
    vector<bool> columnAllowNull(schema_size, true);
    vector<bool> columnInBytes;

    for (int i = 0; i < schema_size; i++)
    {
        //TODO: SchemaColumn is a sad little class that holds an expression pointer,
        // a column name that only really comes in handy in one quirky special case,
        // (see UpdateExecutor::p_init) and a bunch of other stuff that doesn't get used.
        // Someone should put that class out of our misery.
        SchemaColumn* col = outputSchema[i];
        AbstractExpression * expr = col->getExpression();
        columnTypes.push_back(expr->getValueType());
        columnSizes.push_back(expr->getValueSize());
        columnInBytes.push_back(expr->getInBytes());
    }

    TupleSchema* schema =
        TupleSchema::createTupleSchema(columnTypes, columnSizes,
                                       columnAllowNull, columnInBytes);
    return schema;
}
Exemple #2
0
bool AggregateExecutorBase::p_init(AbstractPlanNode*, TempTableLimits* limits)
{
    AggregatePlanNode* node = dynamic_cast<AggregatePlanNode*>(m_abstractNode);
    assert(node);
    assert(node->getChildren().size() == 1);
    assert(node->getChildren()[0] != NULL);

    m_inputExpressions = node->getAggregateInputExpressions();
    for (int i = 0; i < m_inputExpressions.size(); i++) {
        VOLT_DEBUG("\nAGG INPUT EXPRESSION: %s\n",
                   m_inputExpressions[i] ? m_inputExpressions[i]->debug().c_str() : "null");
    }

    /*
     * Find the difference between the set of aggregate output columns
     * (output columns resulting from an aggregate) and output columns.
     * Columns that are not the result of aggregates are being passed
     * through from the input table. Do this extra work here rather then
     * serialize yet more data.
     */
    std::vector<bool> outputColumnsResultingFromAggregates(node->getOutputSchema().size(), false);
    std::vector<int> aggregateOutputColumns = node->getAggregateOutputColumns();
    BOOST_FOREACH(int aOC, aggregateOutputColumns) {
        outputColumnsResultingFromAggregates[aOC] = true;
    }

    /*
     * Now collect the indices in the output table of the pass
     * through columns.
     */
    for (int ii = 0; ii < outputColumnsResultingFromAggregates.size(); ii++) {
        if (outputColumnsResultingFromAggregates[ii] == false) {
            m_passThroughColumns.push_back(ii);
        }
    }

    setTempOutputTable(limits);

    m_aggTypes = node->getAggregates();
    m_distinctAggs = node->getDistinctAggregates();
    m_groupByExpressions = node->getGroupByExpressions();
    node->collectOutputExpressions(m_outputColumnExpressions);
    m_aggregateOutputColumns = node->getAggregateOutputColumns();
    m_prePredicate = node->getPrePredicate();
    m_postPredicate = node->getPostPredicate();

    std::vector<ValueType> groupByColumnTypes;
    std::vector<int32_t> groupByColumnSizes;
    std::vector<bool> groupByColumnAllowNull;
    for (int ii = 0; ii < m_groupByExpressions.size(); ii++) {
        AbstractExpression* expr = m_groupByExpressions[ii];
        groupByColumnTypes.push_back(expr->getValueType());
        groupByColumnSizes.push_back(expr->getValueSize());
        groupByColumnAllowNull.push_back(true);
    }
    m_groupByKeySchema = TupleSchema::createTupleSchema(groupByColumnTypes,
                                                        groupByColumnSizes,
                                                        groupByColumnAllowNull,
                                                        true);
    return true;
}