Esempio n. 1
0
TEST_F(TableTupleTest, VolatileStandAloneTuple) {
    UniqueEngine engine = UniqueEngineBuilder().build();

    // A schema with
    //    - one fixed size column
    //    - one inlined variable-length column
    //    - one non-inlined variable-length column
    ScopedTupleSchema schema{Tools::buildSchema(VALUE_TYPE_BIGINT,
                                                std::make_pair(VALUE_TYPE_VARCHAR, 12),
                                                std::make_pair(VALUE_TYPE_VARCHAR, 256))};
    StandAloneTupleStorage standAloneTuple{schema.get()};
    TableTuple tuple = standAloneTuple.tuple();
    Tools::setTupleValues(&tuple, int64_t(0), "foo", "foo bar");

    // Stand alone tuples are similar to pool-backed tuples.
    ASSERT_TRUE(tuple.inlinedDataIsVolatile());
    ASSERT_FALSE(tuple.nonInlinedDataIsVolatile());

    NValue nv = tuple.getNValue(0);
    ASSERT_FALSE(nv.getVolatile());

    nv = tuple.getNValue(1);
    ASSERT_TRUE(nv.getVolatile());

    nv = tuple.getNValue(2);
    ASSERT_FALSE(nv.getVolatile());
}
Esempio n. 2
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TEST_F(TableTupleTest, VolatileTempTuplePersistent) {
    UniqueEngine engine = UniqueEngineBuilder().build();

    // A schema with
    //    - one fixed-length column
    //    - one inlined variable-length column
    //    - one non-inlined variable-length column
    TupleSchema *schema = Tools::buildSchema(VALUE_TYPE_BIGINT,
                                             std::make_pair(VALUE_TYPE_VARCHAR, 12),
                                             std::make_pair(VALUE_TYPE_VARCHAR, 256));
    std::vector<std::string> columnNames{"id", "inlined", "noninlined"};
    char signature[20];
    std::unique_ptr<Table> table{TableFactory::getPersistentTable(0,
                                                                  "perstbl",
                                                                  schema,
                                                                  columnNames,
                                                                  signature)};
    TableTuple tuple = table->tempTuple();
    Tools::setTupleValues(&tuple, int64_t(0), "foo", "foo bar");

    ASSERT_TRUE(tuple.inlinedDataIsVolatile());
    ASSERT_FALSE(tuple.nonInlinedDataIsVolatile());

    NValue nv = tuple.getNValue(0);
    ASSERT_FALSE(nv.getVolatile());

    nv = tuple.getNValue(1);
    ASSERT_TRUE(nv.getVolatile());

    nv = tuple.getNValue(2);
    ASSERT_FALSE(nv.getVolatile());

    table->insertTuple(tuple);
    TableIterator it = table->iterator();
    TableTuple iterTuple{schema};
    while (it.next(iterTuple)) {
        // Regular, TupleBlock-backed tuples are never volatile.
        ASSERT_FALSE(iterTuple.inlinedDataIsVolatile());
        ASSERT_FALSE(iterTuple.nonInlinedDataIsVolatile());

        nv = iterTuple.getNValue(0);
        ASSERT_FALSE(nv.getVolatile());

        nv = iterTuple.getNValue(1);
        ASSERT_FALSE(nv.getVolatile());

        nv = iterTuple.getNValue(2);
        ASSERT_FALSE(nv.getVolatile());
    }
}
Esempio n. 3
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TEST_F(LargeTempTableTest, Basic) {
    UniqueEngine engine = UniqueEngineBuilder().build();
    LargeTempTableBlockCache* lttBlockCache = ExecutorContext::getExecutorContext()->lttBlockCache();

    TupleSchema* schema = Tools::buildSchema(VALUE_TYPE_BIGINT,
                                             VALUE_TYPE_DOUBLE,
                                             std::make_pair(VALUE_TYPE_VARCHAR, 15),
                                             std::make_pair(VALUE_TYPE_VARCHAR, 128));
    std::vector<std::string> columnNames{
        "pk", "val", "inline_text", "noninline_text"
    };
    auto ltt = makeUniqueTable(TableFactory::buildLargeTempTable(
        "ltmp",
        schema,
        columnNames));

    TableTuple tuple = ltt->tempTuple();

    // Temp tuple for large temp tables is like the temp tuple for
    // normal temp tables and persistent tables:
    //   - inlined, variable-length data is volatile
    //   - non-inlined, variable-length data is in the temp string pool,
    //     which is not volatile.
    ASSERT_TRUE(tuple.inlinedDataIsVolatile());
    ASSERT_FALSE(tuple.nonInlinedDataIsVolatile());

    std::vector<int64_t> pkVals{66, 67, 68};
    std::vector<double> floatVals{3.14, 6.28, 7.77};
    std::vector<std::string> inlineTextVals{"foo", "bar", "baz"};
    std::vector<std::string> nonInlineTextVals{"ffoo", "bbar", "bbaz"};

    ASSERT_EQ(0, lttBlockCache->numPinnedEntries());
    for (int i = 0; i < pkVals.size(); ++i) {
        Tools::setTupleValues(&tuple, pkVals[i], floatVals[i], inlineTextVals[i], nonInlineTextVals[i]);
        ltt->insertTuple(tuple);
    }

    ASSERT_EQ(1, lttBlockCache->numPinnedEntries());

    try {
        TableIterator it = ltt->iterator();
        ASSERT_TRUE_WITH_MESSAGE(false, "Expected release of pinned block to fail");
    }
    catch (const SerializableEEException &exc) {
        ASSERT_NE(std::string::npos, exc.message().find("Attempt to iterate over large temp table before finishInserts() is called"));
    }

    ltt->finishInserts();

    // finishInserts is idempotent and may be called multiple times
    ltt->finishInserts();

    try {
        Tools::setTupleValues(&tuple, int64_t(-1), 3.14, "dino", "ddino");
        ltt->insertTuple(tuple);
        ASSERT_TRUE_WITH_MESSAGE(false, "Expected insertTuple() to fail after finishInserts() called");
    }
    catch (const SerializableEEException& exc) {
        ASSERT_NE(std::string::npos, exc.message().find("Attempt to insert after finishInserts() called"));
    }

    ASSERT_EQ(0, lttBlockCache->numPinnedEntries());

    {
        TableIterator iter = ltt->iterator();
        TableTuple iterTuple(ltt->schema());
        int i = 0;
        while (iter.next(iterTuple)) {
            if (! assertTupleValuesEqual(&iterTuple,
                                         pkVals[i],
                                         floatVals[i],
                                         inlineTextVals[i],
                                         nonInlineTextVals[i])) {
                break;
            }
            ++i;
        }

        ASSERT_EQ(pkVals.size(), i);
    }

    ltt->deleteAllTempTuples();

    ASSERT_EQ(0, lttBlockCache->totalBlockCount());
    ASSERT_EQ(0, lttBlockCache->allocatedMemory());
}
Esempio n. 4
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TEST_F(LargeTempTableTest, MultiBlock) {
    UniqueEngine engine = UniqueEngineBuilder().build();
    LargeTempTableBlockCache* lttBlockCache = ExecutorContext::getExecutorContext()->lttBlockCache();
    ASSERT_EQ(0, lttBlockCache->totalBlockCount());

    const int INLINE_LEN = 15;
    const int NONINLINE_LEN = 50000;

    std::vector<std::string> names{
        "pk",
        "val0",
        "val1",
        "val2",
        "dec0",
        "dec1",
        "dec2",
        "text0",
        "text1",
        "text2",
        "bigtext"
    };

    TupleSchema* schema = Tools::buildSchema(
        //                                       status byte: 1
        VALUE_TYPE_BIGINT,                                //  8
        VALUE_TYPE_DOUBLE,                                //  8
        VALUE_TYPE_DOUBLE,                                //  8
        VALUE_TYPE_DOUBLE,                                //  8
        VALUE_TYPE_DECIMAL,                               // 16
        VALUE_TYPE_DECIMAL,                               // 16
        VALUE_TYPE_DECIMAL,                               // 16
        std::make_pair(VALUE_TYPE_VARCHAR, INLINE_LEN),   // 61
        std::make_pair(VALUE_TYPE_VARCHAR, INLINE_LEN),   // 61
        std::make_pair(VALUE_TYPE_VARCHAR, INLINE_LEN),   // 61
        std::make_pair(VALUE_TYPE_VARCHAR, NONINLINE_LEN)); //  8 (pointer to non-inlined)
    // --> Tuple length is 272 bytes (not counting non-inlined data)

    auto ltt = makeUniqueTable(TableFactory::buildLargeTempTable(
        "ltmp",
        schema,
        names));

    TableTuple tuple = ltt->tempTuple();
    ASSERT_EQ(0, lttBlockCache->numPinnedEntries());

    const int NUM_TUPLES = 500;
    // Attempt to insert enough rows so that we have more than one
    // block in this table.
    //   inline data:
    //                 136000    (500 * 272)
    //
    // Four kinds of non-inlined strings:
    //   NULL               0    (125 * 0)
    //   empty string    1500    (125 * 12, StringRef and length prefix)
    //   half string  3126500    (125 * (25000 + 12))
    //   whole string 6251500    (125 * (50000 + 12))
    //
    // Total -->      9515500
    //
    // LTT blocks are 8MB so this data should use two blocks.
    for (int64_t i = 0; i < NUM_TUPLES; ++i) {
        Tools::setTupleValues(&tuple,
                              i,
                              0.5 * i,
                              0.5 * i + 1,
                              0.5 * i + 2,
                              Tools::toDec(0.5 * i),
                              Tools::toDec(0.5 * i + 1),
                              Tools::toDec(0.5 * i + 2),
                              getStringValue(INLINE_LEN, i),
                              getStringValue(INLINE_LEN, i + 1),
                              getStringValue(INLINE_LEN, i + 2),
                              getStringValue(NONINLINE_LEN, i));
        ASSERT_TRUE(tuple.inlinedDataIsVolatile());
        ASSERT_FALSE(tuple.nonInlinedDataIsVolatile());
        ltt->insertTuple(tuple);
    }

    // The block we were inserting into will be pinned
    ASSERT_EQ(1, lttBlockCache->numPinnedEntries());

    // Indicate that we are done inserting...
    ltt->finishInserts();

    // Block is now unpinned
    ASSERT_EQ(0, lttBlockCache->numPinnedEntries());

    ASSERT_EQ(2, ltt->allocatedBlockCount());

    {
        TableIterator iter = ltt->iterator();
        TableTuple iterTuple(ltt->schema());
        int64_t i = 0;
        while (iter.next(iterTuple)) {
            boost::optional<std::string> inlineStr0 = getStringValue(INLINE_LEN, i);
            boost::optional<std::string> inlineStr1 = getStringValue(INLINE_LEN, i + 1);
            boost::optional<std::string> inlineStr2 = getStringValue(INLINE_LEN, i + 2);
            boost::optional<std::string> nonInlineStr = getStringValue(NONINLINE_LEN, i);

            assertTupleValuesEqual(&iterTuple,
                                   i,
                                   0.5 * i,
                                   0.5 * i + 1,
                                   0.5 * i + 2,
                                   Tools::toDec(0.5 * i),
                                   Tools::toDec(0.5 * i + 1),
                                   Tools::toDec(0.5 * i + 2),
                                   inlineStr0,
                                   inlineStr1,
                                   inlineStr2,
                                   nonInlineStr);
            // Check volatility of inserted values
            NValue nv = iterTuple.getNValue(0);
            ASSERT_FALSE(nv.getVolatile()); // bigint

            nv = iterTuple.getNValue(7); // inlined varchar
            ASSERT_TRUE(nv.getVolatile());

            // It can be made non-volatile by allocating in a pool:
            nv.allocateObjectFromPool();
            ASSERT_FALSE(nv.getVolatile());
            ASSERT_EQ(0, Tools::nvalueCompare(inlineStr0, nv));

            nv = iterTuple.getNValue(10); // non-inlined varchar
            ASSERT_TRUE(nv.getVolatile());

            // It can be made non-volatile by allocating in a pool:
            nv.allocateObjectFromPool();
            ASSERT_FALSE(nv.getVolatile());
            ASSERT_EQ(0, Tools::nvalueCompare(nonInlineStr, nv));

            ++i;
        }

        ASSERT_EQ(500, i);
    }

    ltt->deleteAllTempTuples();

    ASSERT_EQ(0, lttBlockCache->totalBlockCount());
    ASSERT_EQ(0, lttBlockCache->allocatedMemory());
}