ax.benchmark¶

Benchmark Method¶

class ax.benchmark.benchmark_method.BenchmarkMethod(name: str, generation_strategy: GenerationStrategy, scheduler_options: SchedulerOptions)[source]¶

Bases: Base

Benchmark method, represented in terms of Ax generation strategy (which tells us which models to use when) and scheduler options (which tell us extra execution information like maximum parallelism, early stopping configuration, etc.). Note: if BenchmarkMethod.scheduler_optionss.total_trials is lower than BenchmarkProblem.num_trials only the number of trials specified in the former will be run.

generation_strategy: GenerationStrategy¶

name: str¶

scheduler_options: SchedulerOptions¶

ax.benchmark.benchmark_method.get_sequential_optimization_scheduler_options() → SchedulerOptions[source]¶

The typical SchedulerOptions used in benchmarking.

Benchmark Problem¶

class ax.benchmark.benchmark_problem.BenchmarkProblem(name: str, search_space: ~ax.core.search_space.SearchSpace, optimization_config: ~ax.core.optimization_config.OptimizationConfig, runner: ~ax.core.runner.Runner, num_trials: int, tracking_metrics: ~typing.List[~ax.core.metric.Metric] = <factory>)[source]¶

Bases: Base

Benchmark problem, represented in terms of Ax search space, optimization config, and runner.

classmethod from_botorch(test_problem: BaseTestProblem, num_trials: int) → BenchmarkProblem[source]¶

Create a BenchmarkProblem from a BoTorch BaseTestProblem using specialized Metrics and Runners. The test problem’s result will be computed on the Runner and retrieved by the Metric.

name: str¶

num_trials: int¶

optimization_config: OptimizationConfig¶

runner: Runner¶

search_space: SearchSpace¶

tracking_metrics: List[Metric]¶

class ax.benchmark.benchmark_problem.MultiObjectiveBenchmarkProblem(maximum_hypervolume: float, reference_point: List[float], **kwargs)[source]¶

Bases: BenchmarkProblem

A BenchmarkProblem support multiple objectives. Rather than knowing each objective’s optimal value we track a known maximum hypervolume computed from a given reference point.

classmethod from_botorch_multi_objective(test_problem: MultiObjectiveTestProblem, num_trials: int) → MultiObjectiveBenchmarkProblem[source]¶

Create a BenchmarkProblem from a BoTorch BaseTestProblem using specialized Metrics and Runners. The test problem’s result will be computed on the Runner once per trial and each Metric will retrieve its own result by index.

maximum_hypervolume: float¶

reference_point: List[float]¶

class ax.benchmark.benchmark_problem.SingleObjectiveBenchmarkProblem(optimal_value: float, **kwargs)[source]¶

Bases: BenchmarkProblem

The most basic BenchmarkProblem, with a single objective and a known optimal value.

classmethod from_botorch_synthetic(test_problem: SyntheticTestFunction, num_trials: int) → SingleObjectiveBenchmarkProblem[source]¶

Create a BenchmarkProblem from a BoTorch BaseTestProblem using specialized Metrics and Runners. The test problem’s result will be computed on the Runner and retrieved by the Metric.

optimal_value: float¶

Benchmark Result¶

class ax.benchmark.benchmark_result.AggregatedBenchmarkResult(name: str, results: List[BenchmarkResult], optimization_trace: pandas.DataFrame, score_trace: pandas.DataFrame, fit_time: List[float], gen_time: List[float])[source]¶

Bases: Base

The result of a benchmark test, or series of replications. Scalar data present in the BenchmarkResult is here represented as (mean, sem) pairs. More information will be added to the AggregatedBenchmarkResult as the suite develops.

fit_time: List[float]¶

classmethod from_benchmark_results(results: List[BenchmarkResult]) → AggregatedBenchmarkResult[source]¶

Aggregrates a list of BenchmarkResults. For various reasons (timeout, errors, etc.) each BenchmarkResult may have a different number of trials; aggregated traces and statistics are computed with and truncated to the minimum trial count to ensure each replication is included.

gen_time: List[float]¶

name: str¶

optimization_trace: pandas.DataFrame¶

optimization_trace_by_progression(final_progression_only: bool = False) → pandas.DataFrame[source]¶

results: List[BenchmarkResult]¶

score_trace: pandas.DataFrame¶

class ax.benchmark.benchmark_result.BenchmarkResult(name: str, seed: int, experiment: Experiment, optimization_trace: ndarray, score_trace: ndarray, fit_time: float, gen_time: float)[source]¶

Bases: Base

The result of a single optimization loop from one (BenchmarkProblem, BenchmarkMethod) pair. More information will be added to the BenchmarkResult as the suite develops.

experiment: Experiment¶

fit_time: float¶

gen_time: float¶

name: str¶

optimization_trace: ndarray¶

optimization_trace_by_progression(final_progression_only: bool = False) → Tuple[ndarray, ndarray][source]¶

score_trace: ndarray¶

seed: int¶

Benchmark¶

Scored Benchmark¶

Benchmark Methods GPEI and MOO¶

ax.benchmark.methods.gpei_and_moo.get_gpei_default() → BenchmarkMethod[source]¶

ax.benchmark.methods.gpei_and_moo.get_moo_default() → BenchmarkMethod[source]¶

Benchmark Methods Modular BoTorch¶

ax.benchmark.methods.modular_botorch.get_sobol_botorch_modular_acquisition(acquisition_cls: Type[AcquisitionFunction], acquisition_options: Optional[Dict[str, Any]] = None) → BenchmarkMethod[source]¶

ax.benchmark.methods.modular_botorch.get_sobol_botorch_modular_default() → BenchmarkMethod[source]¶

ax.benchmark.methods.modular_botorch.get_sobol_botorch_modular_fixed_noise_gp_qnehvi() → BenchmarkMethod[source]¶

ax.benchmark.methods.modular_botorch.get_sobol_botorch_modular_fixed_noise_gp_qnei() → BenchmarkMethod[source]¶

ax.benchmark.methods.modular_botorch.get_sobol_botorch_modular_saas_fully_bayesian_single_task_gp_qnehvi() → BenchmarkMethod[source]¶

ax.benchmark.methods.modular_botorch.get_sobol_botorch_modular_saas_fully_bayesian_single_task_gp_qnei() → BenchmarkMethod[source]¶

Benchmark Methods SAASBO¶

ax.benchmark.methods.saasbo.get_saasbo_default() → BenchmarkMethod[source]¶

ax.benchmark.methods.saasbo.get_saasbo_moo_default() → BenchmarkMethod[source]¶

Benchmark Methods Choose Generation Strategy¶

ax.benchmark.methods.choose_generation_strategy.get_choose_generation_strategy_method(problem: BenchmarkProblem) → BenchmarkMethod[source]¶

Benchmark Problems Registry¶

class ax.benchmark.problems.registry.BenchmarkProblemRegistryEntry(factory_fn: Callable[..., ax.benchmark.benchmark_problem.BenchmarkProblem], factory_kwargs: Dict[str, Any])[source]¶

Bases: object

factory_fn: Callable[[...], BenchmarkProblem]¶

factory_kwargs: Dict[str, Any]¶

ax.benchmark.problems.registry.get_problem(problem_name: str) → BenchmarkProblem[source]¶

Benchmark Problems High Dimensional Embedding¶

ax.benchmark.problems.hd_embedding.embed_higher_dimension(problem: BenchmarkProblem, total_dimensionality: int) → BenchmarkProblem[source]¶

Benchmark Problems Surrogate¶

class ax.benchmark.problems.surrogate.SurrogateBenchmarkProblem(optimal_value: float, **kwargs)[source]¶

Bases: SingleObjectiveBenchmarkProblem

classmethod from_surrogate(name: str, search_space: SearchSpace, surrogate: Surrogate, datasets: List[SupervisedDataset], minimize: bool, optimal_value: float, num_trials: int) → SurrogateBenchmarkProblem[source]¶

name: str¶

num_trials: int¶

optimal_value: float¶

optimization_config: OptimizationConfig¶

runner: Runner¶

search_space: SearchSpace¶

tracking_metrics: List[Metric]¶

class ax.benchmark.problems.surrogate.SurrogateMetric[source]¶

Bases: Metric

fetch_trial_data(trial: BaseTrial, **kwargs) → Data[source]¶

Fetch data for one trial.

class ax.benchmark.problems.surrogate.SurrogateRunner(name: str, surrogate: Surrogate, datasets: List[SupervisedDataset], search_space: SearchSpace)[source]¶

Bases: Runner

classmethod deserialize_init_args(args: Dict[str, Any]) → Dict[str, Any][source]¶

Given a dictionary, deserialize the properties needed to initialize the object. Used for storage.

poll_trial_status(trials: Iterable[BaseTrial]) → Dict[TrialStatus, Set[int]][source]¶

Checks the status of any non-terminal trials and returns their indices as a mapping from TrialStatus to a list of indices. Required for runners used with Ax Scheduler.

NOTE: Does not need to handle waiting between polling calls while trials are running; this function should just perform a single poll.

Parameters:

trials – Trials to poll.

Returns:

A dictionary mapping TrialStatus to a list of trial indices that have the respective status at the time of the polling. This does not need to include trials that at the time of polling already have a terminal (ABANDONED, FAILED, COMPLETED) status (but it may).

run(trial: BaseTrial) → Dict[str, Any][source]¶

Deploys a trial based on custom runner subclass implementation.

Parameters:

trial – The trial to deploy.

Returns:

Dict of run metadata from the deployment process.

classmethod serialize_init_args(obj: Any) → Dict[str, Any][source]¶

Serialize the properties needed to initialize the runner. Used for storage.

WARNING: Because of issues with consistently saving and loading BoTorch and GPyTorch modules the SurrogateRunner cannot be serialized at this time. At load time the runner will be replaced with a SyntheticRunner.

Benchmark Problems Jenatton¶

ax.benchmark.problems.synthetic.hss.jenatton.get_jenatton_benchmark_problem(num_trials: int = 50) → SingleObjectiveBenchmarkProblem[source]¶

Benchmark Problems PyTorchCNN¶

class ax.benchmark.problems.hpo.pytorch_cnn.PyTorchCNNBenchmarkProblem(optimal_value: float, **kwargs)[source]¶

Bases: SingleObjectiveBenchmarkProblem

classmethod from_datasets(name: str, num_trials: int, train_set: Dataset, test_set: Dataset) → PyTorchCNNBenchmarkProblem[source]¶

name: str¶

num_trials: int¶

optimal_value: float¶

optimization_config: OptimizationConfig¶

runner: Runner¶

search_space: SearchSpace¶

tracking_metrics: List[Metric]¶

class ax.benchmark.problems.hpo.pytorch_cnn.PyTorchCNNMetric[source]¶

Bases: Metric

fetch_trial_data(trial: BaseTrial, **kwargs) → Data[source]¶

Fetch data for one trial.

class ax.benchmark.problems.hpo.pytorch_cnn.PyTorchCNNRunner(name: str, train_set: Dataset, test_set: Dataset)[source]¶

Bases: Runner

class CNN[source]¶

Bases: Module

forward(x)[source]¶

Defines the computation performed at every call.

Should be overridden by all subclasses.

Note

Although the recipe for forward pass needs to be defined within this function, one should call the Module instance afterwards instead of this since the former takes care of running the registered hooks while the latter silently ignores them.

training: bool¶

poll_trial_status(trials: Iterable[BaseTrial]) → Dict[TrialStatus, Set[int]][source]¶

Checks the status of any non-terminal trials and returns their indices as a mapping from TrialStatus to a list of indices. Required for runners used with Ax Scheduler.

NOTE: Does not need to handle waiting between polling calls while trials are running; this function should just perform a single poll.

Parameters:

trials – Trials to poll.

Returns:

A dictionary mapping TrialStatus to a list of trial indices that have the respective status at the time of the polling. This does not need to include trials that at the time of polling already have a terminal (ABANDONED, FAILED, COMPLETED) status (but it may).

run(trial: BaseTrial) → Dict[str, Any][source]¶

Deploys a trial based on custom runner subclass implementation.

Parameters:

trial – The trial to deploy.

Returns:

Dict of run metadata from the deployment process.

train_and_evaluate(lr: float, momentum: float, weight_decay: float, step_size: int, gamma: float) → float[source]¶

Benchmark Problems PyTorchCNN TorchVision¶

class ax.benchmark.problems.hpo.torchvision.PyTorchCNNTorchvisionBenchmarkProblem(optimal_value: float, **kwargs)[source]¶

Bases: PyTorchCNNBenchmarkProblem

classmethod from_dataset_name(name: str, num_trials: int) → PyTorchCNNTorchvisionBenchmarkProblem[source]¶

name: str¶

num_trials: int¶

optimal_value: float¶

optimization_config: OptimizationConfig¶

runner: Runner¶

search_space: SearchSpace¶

tracking_metrics: List[Metric]¶

class ax.benchmark.problems.hpo.torchvision.PyTorchCNNTorchvisionRunner(name: str, train_set: Dataset, test_set: Dataset)[source]¶

Bases: PyTorchCNNRunner

A subclass to aid in serialization. This allows us to save only the name of the dataset and reload it from TorchVision at deserialization time.

classmethod deserialize_init_args(args: Dict[str, Any]) → Dict[str, Any][source]¶

Given a dictionary, deserialize the properties needed to initialize the object. Used for storage.

classmethod serialize_init_args(obj: Any) → Dict[str, Any][source]¶

Serialize the properties needed to initialize the object. Used for storage.