test-example-projects/c++_projects/280w-mysql-8.0.18/unittest/gunit/opt_guessrecperkey-t.cc

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// First include (the generated) my_config.h, to get correct platform defines.
#include "my_config.h"

#include <gtest/gtest.h>
#include <sys/types.h>

#include "sql/key.h"                    // KEY
#include "sql/opt_statistics.h"         // guess_rec_per_key
#include "unittest/gunit/fake_key.h"    // Fake_KEY
#include "unittest/gunit/fake_table.h"  // Fake_TABLE
#include "unittest/gunit/test_utils.h"

namespace guessrecperkey_unittest {

using my_testing::Server_initializer;

class GuessRecPerKeyTest : public ::testing::Test {
  virtual void SetUp() { initializer.SetUp(); }

  virtual void TearDown() { initializer.TearDown(); }

 private:
  Server_initializer initializer;
};

TEST_F(GuessRecPerKeyTest, GuessRecPerKeyMultiColumn) {
  const uint key_parts = 3;

  Fake_TABLE table(key_parts, false);
  Fake_KEY key(key_parts, false);
  Fake_KEY unique_key(key_parts, true);

  // Table is empty, records per key estimate should be 1
  EXPECT_EQ(guess_rec_per_key(&table, &key, 1), 1.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &key, 2), 1.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &key, 3), 1.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 1), 1.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 2), 1.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 3), 1.0f);

  /*
    Test with a large table and a non-unique key.
  */

  // Increase the size of the table
  const ha_rows large_table_size = 10000;
  table.file->stats.records = large_table_size;

  // Rec per key for first key part should be 1 percent of table size
  EXPECT_FLOAT_EQ(guess_rec_per_key(&table, &key, 1),
                  rec_per_key_t(large_table_size / 100));

  // Rec per key for last key part should be 10 for a non-unique key
  EXPECT_EQ(guess_rec_per_key(&table, &key, 3), 10.0f);

  // Rec per key for the second key part should be somewhere between first
  // and last key part
  rec_per_key_t rec_per_key = guess_rec_per_key(&table, &key, 2);
  EXPECT_LT(rec_per_key, rec_per_key_t(large_table_size / 100));
  EXPECT_GT(rec_per_key, 10.0f);

  /*
    Test with a large table and a unique key.
  */

  // Rec per key for first key part should be 1 percent of table size
  EXPECT_FLOAT_EQ(guess_rec_per_key(&table, &unique_key, 1),
                  rec_per_key_t(large_table_size / 100));

  // Rec per key for last key part should be 1 for a unique key
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 3), 1.0f);

  // Rec per key for the second key part should be somewhere between first
  // and last key part
  rec_per_key = guess_rec_per_key(&table, &unique_key, 2);
  EXPECT_LT(rec_per_key, rec_per_key_t(large_table_size / 100));
  EXPECT_GT(rec_per_key, 1.0f);

  /*
    Test with a small table and a non-unique key.
  */

  // Set the size of the table
  const ha_rows small_table_size = 150;
  table.file->stats.records = small_table_size;

  // Rec per key for first key part should be 1 percent of table size, but
  // not smaller than rec per key for the last key
  EXPECT_EQ(guess_rec_per_key(&table, &key, 1), 10.0f);

  // Rec per key for last key part should be 10 for a non-unique key
  EXPECT_EQ(guess_rec_per_key(&table, &key, 3), 10.0f);

  // Rec per key for the second key part should be somewhere between first
  // and last key part, but in this case they are identical
  EXPECT_EQ(guess_rec_per_key(&table, &key, 2), 10.0f);

  /*
    Test with a small table and a unique key.
  */

  // Rec per key for first key part should be 1 percent of table size
  EXPECT_FLOAT_EQ(guess_rec_per_key(&table, &unique_key, 1),
                  rec_per_key_t(small_table_size) / 100);

  // Rec per key for last key part should be 1 for a unique key
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 3), 1.0f);

  // Rec per key for the second key part should be somewhere between first
  // and last key part
  rec_per_key = guess_rec_per_key(&table, &unique_key, 2);
  EXPECT_LT(rec_per_key, rec_per_key_t(small_table_size) / 100);
  EXPECT_GT(rec_per_key, 1.0f);

  /*
    Test with a tiny table and a non-unique key.
  */

  // Set the size of the table
  const ha_rows tiny_table_size = 30;
  table.file->stats.records = tiny_table_size;

  // Rec per key for first key part should be 1 percent of table size, but
  // not smaller than rec per key for the last key
  EXPECT_FLOAT_EQ(guess_rec_per_key(&table, &key, 1),
                  rec_per_key_t(tiny_table_size) / 10);

  // Rec per key for last key part should be 10 for a non-unique key, but
  // there should be at least then unique values in the table
  EXPECT_FLOAT_EQ(guess_rec_per_key(&table, &key, 3),
                  rec_per_key_t(tiny_table_size) / 10);

  // Rec per key for the second key part should be somewhere between first
  // and last key part, but in this case they are identical
  EXPECT_FLOAT_EQ(guess_rec_per_key(&table, &key, 2),
                  rec_per_key_t(tiny_table_size) / 10);

  /*
    Test with a tiny table and a unique key.
  */

  // Rec per key for first key part should be 1 percent of table size, but
  // not smaller than rec per key for the last key
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 1), 1.0f);

  // Rec per key for last key part should be 1 for a unique key
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 3), 1.0f);

  // Rec per key for the second key part should be somewhere between first
  // and last key part, but in this case they are indentical
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 2), 1.0f);

  /*
    Test that setting rec per key value for the last key part will be
    taken into account.
  */
  key.rec_per_key[key_parts - 1] = 2;

  // This is a tiny table so all rec per keys estimates should be
  // identical to the estimate for the last key
  EXPECT_EQ(guess_rec_per_key(&table, &key, 1), 2.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &key, 2), 2.0f);

  // This even is the case for a unique key
  unique_key.rec_per_key[key_parts - 1] = 2;
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 1), 2.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 2), 2.0f);
}

TEST_F(GuessRecPerKeyTest, GuessRecPerKeySingleColumn) {
  const uint key_parts = 1;

  Fake_TABLE table(key_parts, false);
  Fake_KEY key(key_parts, false);
  Fake_KEY unique_key(key_parts, true);

  // Table is empty, records per key estimate should be 1
  EXPECT_EQ(guess_rec_per_key(&table, &key, 1), 1.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 1), 1.0f);

  /*
    Test with a large table and a non-unique key.
  */

  // Increase the size of the table
  const ha_rows large_table_size = 10000;
  table.file->stats.records = large_table_size;

  // Rec per key for first key part should be 1 percent of table size
  EXPECT_FLOAT_EQ(guess_rec_per_key(&table, &key, 1),
                  rec_per_key_t(large_table_size / 100));
  /*
    Test with a large table and a unique key.
  */

  // Rec per key for a unique index should always be 1
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 1), 1.0f);

  /*
    Test with a small table and a non-unique key.
  */

  // Set the size of the table
  const ha_rows small_table_size = 150;
  table.file->stats.records = small_table_size;

  // Rec per key for a non-unique table should be 1 percent of table size
  // but not lower than 10.
  EXPECT_EQ(guess_rec_per_key(&table, &key, 1), 10.0f);

  /*
    Test with a small table and a unique key.
  */

  // Rec per key for a unique index should always be 1
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 1), 1.0f);

  /*
    Test with a tiny table and a non-unique key.
  */

  // Set the size of the table
  const ha_rows tiny_table_size = 30;
  table.file->stats.records = tiny_table_size;

  // Rec per key for first key part should be 1 percent of table size, but
  // not smaller than 10% of the table
  EXPECT_FLOAT_EQ(guess_rec_per_key(&table, &key, 1),
                  rec_per_key_t(tiny_table_size) / 10);

  /*
    Test with a tiny table and a unique key.
  */

  // Rec per key for a unique index should always be 1
  EXPECT_EQ(guess_rec_per_key(&table, &unique_key, 1), 1.0f);
}

TEST_F(GuessRecPerKeyTest, GuessRecPerKeyIndexExtension) {
  const uint columns = 5;
  const uint pk_parts = 2;
  const uint key_parts = 2;

  Fake_TABLE table(columns, false);
  Fake_KEY key(key_parts, key_parts + pk_parts, false);

  // Table is empty, records per key estimate should be 1
  EXPECT_EQ(guess_rec_per_key(&table, &key, 1), 1.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &key, 2), 1.0f);
  EXPECT_EQ(guess_rec_per_key(&table, &key, 3), 1.0f);
}

}  // namespace guessrecperkey_unittest