C++ (Cpp) mockSlaveUsageの例

コード例 #1

ファイル: qos_pipeline_test.cpp プロジェクト: Bplotka/serenity

TEST(QoSPipelineTest, NoCorrections) {
  uint64_t WINDOWS_SIZE = 10;
  uint64_t CONTENTION_COOLDOWN = 10;
  double_t FRATIONAL_THRESHOLD = 0.5;

  MockSlaveUsage mockSlaveUsage(QOS_PIPELINE_FIXTURE1);

  SerenityConfig conf;
  conf["Detector"] = createAssuranceDetectorCfg(
    WINDOWS_SIZE, CONTENTION_COOLDOWN, FRATIONAL_THRESHOLD);

  conf.set(ENABLED_VISUALISATION, false);
  conf.set(VALVE_OPENED, true);

  QoSControllerPipeline* pipeline = new CpuQoSPipeline(conf);

  // First iteration.
  Result<QoSCorrections> corrections =
      pipeline->run(mockSlaveUsage.usage().get());
  EXPECT_NONE(corrections);

  // Second iteration.
  corrections = pipeline->run(mockSlaveUsage.usage().get());
  EXPECT_SOME(corrections);

  EXPECT_TRUE(corrections.get().empty());

  delete pipeline;
}

コード例 #2

ファイル: qos_pipeline_test.cpp プロジェクト: lelezi/serenity

TEST(QoSPipelineTest, NoCorrections) {
  uint64_t WINDOWS_SIZE = 10;
  uint64_t CONTENTION_COOLDOWN = 10;
  double_t RELATIVE_THRESHOLD = 0.5;

  MockSlaveUsage mockSlaveUsage(QOS_PIPELINE_FIXTURE1);

  QoSControllerPipeline* pipeline =
      new CpuQoSPipeline<RollingChangePointDetector>(
          QoSPipelineConf(
              ChangePointDetectionState::createForRollingDetector(
                  WINDOWS_SIZE,
                  CONTENTION_COOLDOWN,
                  RELATIVE_THRESHOLD),
              ema::DEFAULT_ALPHA,
              false,
              true));

  // First iteration.
  Result<QoSCorrections> corrections =
      pipeline->run(mockSlaveUsage.usage().get());
  EXPECT_NONE(corrections);

  // Second iteration.
  corrections = pipeline->run(mockSlaveUsage.usage().get());
  EXPECT_SOME(corrections);

  EXPECT_TRUE(corrections.get().empty());

  delete pipeline;
}

コード例 #3

ファイル: qos_pipeline_test.cpp プロジェクト: Bplotka/serenity

TEST(QoSIpcPipelineTest, AssuranceDetectorTwoDropCorrectionsWithEma) {
  uint64_t WINDOWS_SIZE = 10;
  uint64_t CONTENTION_COOLDOWN = 4;
  double_t FRATIONAL_THRESHOLD = 0.3;
  double_t SEVERITY_LEVEL = 1;
  double_t NEAR_LEVEL = 0.1;

  MockSlaveUsage mockSlaveUsage(QOS_PIPELINE_FIXTURE2);

  SerenityConfig conf;
  conf["Detector"] = createAssuranceDetectorCfg(
    WINDOWS_SIZE,
    CONTENTION_COOLDOWN,
    FRATIONAL_THRESHOLD,
    SEVERITY_LEVEL,
    NEAR_LEVEL);
  conf.set(ema::ALPHA, 0.9);
  conf.set(ENABLED_VISUALISATION, false);
  conf.set(VALVE_OPENED, true);

  QoSControllerPipeline* pipeline = new CpuQoSPipeline(conf);

  // First iteration.
  Result<QoSCorrections> corrections =
      pipeline->run(mockSlaveUsage.usage().get());
  EXPECT_NONE(corrections);

  ResourceUsage usage = mockSlaveUsage.usage().get();
  const int32_t LOAD_ITERATIONS = 17;
  LoadGenerator loadGen(
      [](double_t iter) { return 1; },
      new ZeroNoise(),
      LOAD_ITERATIONS);

  for (; loadGen.end(); loadGen++) {
    // Test scenario: After 10 iterations create drop in IPC
    // for executor num 3.
    double_t ipcFor3Executor = (*loadGen)();
    if (loadGen.iteration >= 11) {
      ipcFor3Executor /= 2.0;
    }

    usage.mutable_executors(PR_4CPUS)->CopyFrom(
        generateIPC(usage.executors(PR_4CPUS),
                    ipcFor3Executor,
                    (*loadGen).timestamp));

    usage.mutable_executors(PR_2CPUS)->CopyFrom(
        generateIPC(usage.executors(PR_2CPUS),
                    (*loadGen)(),
                    (*loadGen).timestamp));
    // Third iteration (repeated).
    corrections = pipeline->run(usage);

    // Assurance Detector will wait for signal to be returned to the
    // established state.
    if (loadGen.iteration == 11 || loadGen.iteration == 16) {
      EXPECT_SOME(corrections);
      ASSERT_EQ(slave::QoSCorrection_Type_KILL,
                corrections.get().front().type());
      // Make sure that we do not kill PR tasks!
      EXPECT_NE("serenityPR",
                corrections.get().front().kill().executor_id().value());
      EXPECT_NE("serenityPR2",
                corrections.get().front().kill().executor_id().value());
    } else {
      EXPECT_SOME(corrections);
      EXPECT_TRUE(corrections.get().empty());
    }
  }

  delete pipeline;
}

コード例 #4

ファイル: qos_pipeline_test.cpp プロジェクト: lelezi/serenity

TEST(QoSIpsPipelineTest, RollingFractionalDetectorOneDropCorrectionsWithEma) {
  QoSPipelineConf conf;
  ChangePointDetectionState cpdState;
  // Detector configuration:
  // How far we look back in samples.
  cpdState.windowSize = 10;
  // How many iterations detector will wait with creating another
  // contention.
  cpdState.contentionCooldown = 10;
  // Defines how much (relatively to base point) value must drop to trigger
  // contention.
  // Most detectors will use that.
  cpdState.fractionalThreshold = 0.5;
  // Defines how many instructions can be done per one CPU in one second.
  // This option helps RollingFractionalDetector to estimate severity of
  // drop.
  cpdState.severityLevel = 1000000000;  // 1 Billion.

  conf.cpdState = cpdState;
  conf.emaAlpha = 0.4;
  conf.visualisation = false;
  // Let's start with QoS pipeline disabled.
  conf.valveOpened = true;

  MockSlaveUsage mockSlaveUsage(QOS_PIPELINE_FIXTURE3);

  QoSControllerPipeline* pipeline =
    new IpsQoSPipeline<RollingFractionalDetector>(conf);

  // First iteration.
  Result<QoSCorrections> corrections =
      pipeline->run(mockSlaveUsage.usage().get());
  EXPECT_NONE(corrections);

  // Second iteration is used for manually configured load.
  ResourceUsage usage = mockSlaveUsage.usage().get();
  const int32_t LOAD_ITERATIONS = 14;
  LoadGenerator loadGen(
      [](double_t iter) { return 3000000000; },
      new ZeroNoise(),
      LOAD_ITERATIONS);

  for (; loadGen.end(); loadGen++) {
    // Test scenario: After 10 iterations create drop in IPS for executor num 3.
    double ipsFor3Executor = (*loadGen)();
    if (loadGen.iteration >= 11) {
      ipsFor3Executor /= 3.0;
    }

    usage.mutable_executors(PR_4CPUS)->CopyFrom(
        generateIPS(usage.executors(PR_4CPUS),
                    ipsFor3Executor,
                    (*loadGen).timestamp));

    usage.mutable_executors(PR_2CPUS)->CopyFrom(
        generateIPS(usage.executors(PR_2CPUS),
                    (*loadGen)(),
                    (*loadGen).timestamp));
    // Third iteration (repeated).
    corrections = pipeline->run(usage);
    if (loadGen.iteration >= 13) {
      EXPECT_SOME(corrections);
      ASSERT_EQ(slave::QoSCorrection_Type_KILL,
                corrections.get().front().type());
      // Make sure that we do not kill PR tasks!
      EXPECT_NE("serenityPR",
                corrections.get().front().kill().executor_id().value());
      EXPECT_NE("serenityPR2",
                corrections.get().front().kill().executor_id().value());
    } else {
      EXPECT_SOME(corrections);
      EXPECT_TRUE(corrections.get().empty());
    }
  }

  delete pipeline;
}

コード例 #5

ファイル: qos_pipeline_test.cpp プロジェクト: lelezi/serenity

TEST(QoSIpcPipelineTest,
     AssuranceFractionalDetectorTwoDropCorrectionsWithEma) {
  QoSPipelineConf conf;
  ChangePointDetectionState cpdState;
  // Detector configuration:
  // How far we look back in samples.
  cpdState.windowSize = 10;
  // How many iterations detector will wait with creating another
  // contention.
  cpdState.contentionCooldown = 4;
  // Defines how much (relatively to base point) value must drop to trigger
  // contention.
  // Most detectors will use that.
  cpdState.fractionalThreshold = 0.3;
  // Defines how to convert difference in values to CPU.
  // This option helps RollingFractionalDetector to estimate severity of
  // drop.
  cpdState.severityLevel = 1;
  cpdState.nearFraction = 0.1;

  conf.cpdState = cpdState;
  conf.emaAlpha = 0.9;
  conf.visualisation = false;
  // Let's start with QoS pipeline disabled.
  conf.valveOpened = true;

  MockSlaveUsage mockSlaveUsage(QOS_PIPELINE_FIXTURE2);

  QoSControllerPipeline* pipeline =
      new CpuQoSPipeline<AssuranceFractionalDetector>(conf);

  // First iteration.
  Result<QoSCorrections> corrections =
      pipeline->run(mockSlaveUsage.usage().get());
  EXPECT_NONE(corrections);

  ResourceUsage usage = mockSlaveUsage.usage().get();
  const int32_t LOAD_ITERATIONS = 17;
  LoadGenerator loadGen(
      [](double_t iter) { return 1; },
      new ZeroNoise(),
      LOAD_ITERATIONS);

  for (; loadGen.end(); loadGen++) {
    // Test scenario: After 10 iterations create drop in IPC
    // for executor num 3.
    double_t ipcFor3Executor = (*loadGen)();
    if (loadGen.iteration >= 11) {
      ipcFor3Executor /= 2.0;
    }

    usage.mutable_executors(PR_4CPUS)->CopyFrom(
        generateIPC(usage.executors(PR_4CPUS),
                    ipcFor3Executor,
                    (*loadGen).timestamp));

    usage.mutable_executors(PR_2CPUS)->CopyFrom(
        generateIPC(usage.executors(PR_2CPUS),
                    (*loadGen)(),
                    (*loadGen).timestamp));
    // Third iteration (repeated).
    corrections = pipeline->run(usage);

    // Assurance Detector will wait for signal to be returned to the
    // established state.
    if (loadGen.iteration == 11 || loadGen.iteration == 16) {
      EXPECT_SOME(corrections);
      ASSERT_EQ(slave::QoSCorrection_Type_KILL,
                corrections.get().front().type());
      // Make sure that we do not kill PR tasks!
      EXPECT_NE("serenityPR",
                corrections.get().front().kill().executor_id().value());
      EXPECT_NE("serenityPR2",
                corrections.get().front().kill().executor_id().value());
    } else {
      EXPECT_SOME(corrections);
      EXPECT_TRUE(corrections.get().empty());
    }
  }

  delete pipeline;
}

コード例 #6

ファイル: qos_pipeline_test.cpp プロジェクト: lelezi/serenity

TEST(QoSIpcPipelineTest, RollingDetectorOneDropCorrectionsWithEma) {
  uint64_t WINDOWS_SIZE = 10;
  uint64_t CONTENTION_COOLDOWN = 10;
  double_t RELATIVE_THRESHOLD = 0.3;

  MockSlaveUsage mockSlaveUsage(QOS_PIPELINE_FIXTURE2);

  QoSControllerPipeline* pipeline =
      new CpuQoSPipeline<RollingChangePointDetector>(
          QoSPipelineConf(
              ChangePointDetectionState::createForRollingDetector(
                  WINDOWS_SIZE,
                  CONTENTION_COOLDOWN,
                  RELATIVE_THRESHOLD),
              0.2,  // Alpha = 1 means no smoothing. 0.2 means high smoothing.
              false,
              true));

  // First iteration.
  Result<QoSCorrections> corrections =
      pipeline->run(mockSlaveUsage.usage().get());
  EXPECT_NONE(corrections);

  ResourceUsage usage = mockSlaveUsage.usage().get();
  const int32_t LOAD_ITERATIONS = 16;
  LoadGenerator loadGen(
      [](double_t iter) { return 1; },
      new ZeroNoise(),
      LOAD_ITERATIONS);

  for (; loadGen.end(); loadGen++) {
    // Test scenario: After 10 iterations create drop in
    // IPC for executor num 3.
    double_t ipcFor3Executor = (*loadGen)();
    if (loadGen.iteration >= 11) {
      ipcFor3Executor /= 2.0;
    }

    usage.mutable_executors(PR_4CPUS)->CopyFrom(
        generateIPC(usage.executors(PR_4CPUS),
                    ipcFor3Executor,
                    (*loadGen).timestamp));

    usage.mutable_executors(PR_2CPUS)->CopyFrom(
        generateIPC(usage.executors(PR_2CPUS),
                    (*loadGen)(),
                    (*loadGen).timestamp));
    // Third iteration (repeated).
    corrections = pipeline->run(usage);
    if (loadGen.iteration >= 15) {
      EXPECT_SOME(corrections);
      ASSERT_EQ(slave::QoSCorrection_Type_KILL,
                corrections.get().front().type());
      // Make sure that we do not kill PR tasks!
      EXPECT_NE("serenityPR",
                corrections.get().front().kill().executor_id().value());
      EXPECT_NE("serenityPR2",
                corrections.get().front().kill().executor_id().value());
    } else {
      EXPECT_SOME(corrections);
      EXPECT_TRUE(corrections.get().empty());
    }
  }

  delete pipeline;
}