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Tensorflow Model Analysis Architecture

Overview

The TensorFlow Model Analysis (TFMA) pipeline is depicted as follows:

TFMA Pipeline

The pipeline is made up of four main components:

  • Read Inputs
  • Extraction
  • Evaluation
  • Write Results

These components make use of two primary types: tfma.Extracts and tfma.evaluators.Evaluation. The type tfma.Extracts represents data that is extracted during pipeline processing whereas the type tfma.evaluators.Evaluation represents the output from evaluating the extracts at various points during the process of extraction. In order to provide a flexible API, these types are just dicts where the keys are defined (reserved for use) by different implementations. The types are defined as follows:

# Extracts represent data extracted during pipeline processing.
# For example, the PredictExtractor stores the data for the
# features, labels, and predictions under the keys "features",
# "labels", and "predictions".
Extracts = Dict[Text, Any]

# Evaluation represents the output from evaluating extracts at
# particular point in the pipeline. The evaluation outputs are
# keyed by their associated output type. For example, the metric / plot
# dictionaries from evaluating metrics and plots will be stored under
# "metrics" and "plots" respectively.
Evaluation = Dict[Text, beam.pvalue.PCollection]

Note that tfma.Extracts are never written out directly they must always go through an evaluator to produce a tfma.evaluators.Evaluation that is then written out. Also note that tfma.Extracts are dicts that are stored in a beam.pvalue.PCollection (i.e. beam.PTransforms take as input beam.pvalue.PCollection[tfma.Extracts]) whereas a tfma.evaluators.Evaluation is a dict whose values are beam.pvalue.PCollections (i.e. beam.PTransforms take the dict itself as the argument for the beam.value.PCollection input). In other words the tfma.evaluators.Evaluation is used at pipeline construction time, but the tfma.Extracts are used at pipeline runtime.

Read Inputs

The ReadInputs stage is made up of a transform that takes raw inputs (tf.train.Example, CSV, ...) and converts them into extracts. Today the extracts are represented as raw input bytes stored under tfma.INPUT_KEY, however the extracts can be in any form that is compatible with the extraction pipeline -- meaning that it creates tfma.Extracts as output, and that those extracts are compatible with downstream extractors. It is up to the different extractors to clearly document what they require.

Extraction

The extraction process is a list of beam.PTransforms that are run in series. The extractors take tfma.Extracts as input and return tfma.Extracts as output. The proto-typical extractor is the tfma.extractors.PredictExtractor which uses the input extract produced by the read inputs transform and runs it through a model to produce predictions extracts. Customized extractors can be inserted at any point provided their transforms conform to the tfma.Extracts in and tfma.Extracts out API. An extractor is defined as follows:

# An Extractor is a PTransform that takes Extracts as input and returns
# Extracts as output. A typical example is a PredictExtractor that receives
# an 'input' placeholder for input and adds additional 'predictions' extracts.
Extractor = NamedTuple('Extractor', [
    ('stage_name', Text),
    ('ptransform', beam.PTransform)])  # Extracts -> Extracts

Note that outside of very special cases, it is almost always the case that one tfma.Extracts in a beam.pvalue.PCollection will correspond to one example from the model.

InputExtractor

The tfma.extractors.InputExtractor is used to extract raw features, raw labels, and raw example weights from tf.train.Example records for using in metrics slicing and computations. By default the values are stored under the extract keys features, labels, and example_weights respectively. Single-output model labels and example weights are stored directly as np.ndarray values. Multi-output model labels and example weights are stored as dicts of np.ndarray values (keyed by output name). If multi-model evaluation is performed the labels and example weights will be further embedded within another dict (keyed by model name).

PredictExtractor

The tfma.extractors.PredictExtractor runs model predictions and stores them under the key predictions in the tfma.Extracts dict. Single-output model predictions are stored directly as the predicted output values. Multi-output model predictions are stored as a dict of output values (keyed by output name). If multi-model evaluation is performed the prediction will be further embedded within another dict (keyed by model name). The actual output value used depends on the model (e.g. TF estimator's return outputs in the form of a dict whereas keras returns np.ndarray values).

SliceKeyExtractor

The tfma.extractors.SliceKeyExtractor uses the slicing spec to determine which slices apply to each example input based on the extracted features and adds the coresponding slicing values to the extracts for later used by the evaluators.

Evaluation

Evaluation is the process of taking an extract and evaluating it. While it is common to perform evaluation at the end of the extraction pipeline, there are use-cases that require evaluation earlier in the extraction process. As such evaluators are associated with the extractors whose output they should be evaluated against. An evaluator is defined as follows:

# An evaluator is a PTransform that takes Extracts as input and
# produces an Evaluation as output. A typical example of an evaluator
# is the MetricsAndPlotsEvaluator that takes the 'features', 'labels',
# and 'predictions' extracts from the PredictExtractor and evaluates
# them using post export metrics to produce metrics and plots dictionaries.
Evaluator = NamedTuple('Evaluator', [
  ('stage_name', Text),
  ('run_after', Text),              # Extractor.stage_name
  ('ptransform', beam.PTransform)]) # Extracts -> Evaluation

Notice that an evaluator is a beam.PTransform that takes tfma.Extracts as inputs. There is nothing stopping an implementation from performing additional transformations on the extracts as part of the evaluation process. Unlike extractors that must return a tfma.Extracts dict, there are no restrictions on the types of outputs an evaluator can produce though most evaluators also return a dict (e.g. of metric names and values).

MetricsAndPlotsEvaluator

The tfma.evaluators.MetricsAndPlotsEvaluator takes features, labels, and predictions as input, runs them through tfma.slicer.FanoutSlices to group them by slices, and then performs metrics and plots computations. It produces outputs in the form of dictionaries of metrics and plots keys and values (these are later converted to serialized protos for output by tfma.writers.MetricsAndPlotsWriter).

Write Results

The WriteResults stage is where the evaluation output gets written out to disk. WriteResults uses writers to write out the data based on the output keys. For example, an tfma.evaluators.Evaluation may contain keys for metrics and plots. These would then be associated with the metrics and plots dictionaries called 'metrics' and 'plots'. The writers specify how to write out each file:

# A writer is a PTransform that takes evaluation output as input and
# serializes the associated PCollections of data to a sink.
Writer = NamedTuple('Writer', [
  ('stage_name', Text),
  ('ptransform', beam.PTransform)])    # Evaluation -> PDone

MetricsAndPlotsWriter

We provide a tfma.writers.MetricsAndPlotsWriter that converts the metrics and plots dictionaries to serialized protos and writes them to disk.

If you wish to use a different serialization format, you can create a custom writer and use that instead. Since the tfma.evaluators.Evaluation passed to the writers contains the output for all of the evaluators combined, a tfma.writers.Write helper transform is provided that writers can use in their ptransform implementations to select the appropriate beam.PCollections based on an output key (see below for an example).

Customization

The tfma.run_model_analysis method takes extractors, evaluators, and writers arguments for customing the extractors, evaluators, and writers used by the pipeline. If no arguments are provided then tfma.default_extractors, tfma.default_evaluators, and tfma.default_writers are used by default.

Custom Extractors

To create a custom extractor, create a tfma.extractors.Extractor type that wraps a beam.PTransform taking tfma.Extracts as input and returning tfma.Extracts as output. Examples of extractors are available under tfma.extractors.

Custom Evaluators

To create a custom evaluator, create a tfma.evaluators.Evaluator type that wraps a beam.PTransform taking tfma.Extracts as input and returning tfma.evaluators.Evaluation as output. A very basic evaluator might just take the incoming tfma.Extracts and output them for storing in a table. This is exactly what the tfma.evaluators.AnalysisTableEvaluator does. A more complicated evaluator might perform additional processing and data aggregation. See the tfma.evaluators.MetricsAndPlotsEvaluator as an example..

Note that the tfma.evaluators.MetricsAndPlotsEvaluator itself can be customized to support custom metrics (see metrics for more details).

Custom Writers

To create a custom writer, create a tfma.writers.Writer type that wraps a beam.PTransform taking tfma.evaluators.Evaluation as input and returning beam.pvalue.PDone as output. The following is a basic example of a writer for writing out TFRecords containing metrics:

tfma.writers.Writer(
  stage_name='WriteTFRecord(%s)' % tfma.METRICS_KEY,
  ptransform=tfma.writers.Write(
    key=tfma.METRICS_KEY,
    ptransform=beam.io.WriteToTFRecord(file_path_prefix=output_file))

A writer's inputs depend on the output of the associated evaluator. For the above example, the output is a serialized proto produced by the tfma.evaluators.MetricsAndPlotsEvaluator. A writer for the tfma.evaluators.AnalysisTableEvaluator would be responsible for writing out a beam.pvalue.PCollection of tfma.Extracts.

Note that a writer is associated with the output of an evaluator via the output key used (e.g. tfma.METRICS_KEY, tfma.ANALYSIS_KEY, etc).

Step by Step Example

The following is an example of the steps involved in the extraction and evaluation pipeline when both the tfma.evaluators.MetricsAndPlotsEvaluator and tfma.evaluators.AnalysisTableEvaluator are used:

run_model_analysis(
    ...
    extractors=[
        tfma.extractors.InputExtractor(...),
        tfma.extractors.PredictExtractor(...),
        tfma.extractors.SliceKeyExtrator(...)
    ],
    evaluators=[
        tfma.evaluators.MetricsAndPlotsEvaluator(...),
        tfma.evaluators.AnalysisTableEvaluator(...)
    ])

ReadInputs

# Out
Extracts {
  'input': bytes                 # CSV, Proto, ...
}

ExtractAndEvaluate

  • tfma.extractors.InputExtractor
# In:  ReadInputs Extracts
# Out:
Extracts {
  'input': bytes                    # CSV, Proto, ...
  'features': tensor_like           # Raw features
  'labels': tensor_like             # Labels
  'example_weights': tensor_like    # Example weights
}
  • tfma.extractors.PredictExtractor
# In:  InputExtractor Extracts
# Out:
Extracts {
  'input': bytes                    # CSV, Proto, ...
  'features': tensor_like           # Raw features
  'labels': tensor_like             # Labels
  'example_weights': tensor_like    # Example weights
  'predictions': tensor_like        # Predictions
}
  • tfma.extractors.SliceKeyExtractor
# In: PredictExtractor Extracts
# Out:
Extracts {
  'features': tensor_like           # Raw features
  'labels': tensor_like             # Labels
  'example_weights': tensor_like    # Example weights
  'predictions': tensor_like        # Predictions
  'slice_key': Tuple[bytes...]      # Slice
}
  • tfma.evaluators.MetricsAndPlotsEvaluator (run_after: SLICE_KEY_EXTRACTOR_STAGE_NAME)
# In: SliceKeyExtractor Extracts
# Out:
Evaluation {
  'metrics': PCollection[Tuple[slicer.SliceKeyType, Dict[Text, Any]]]  # Tuples of (slice key, dictionary from metric key to metric values)
  'plots': PCollection[Tuple[slicer.SliceKeyType, Dict[Text, Any]]]  # Tuples of (slice key, dictionary from plot key to plot values)
}
  • tfma.evaluators.AnalysisTableEvaluator (run_after: LAST_EXTRACTOR_STAGE_NAME)
# In: SliceKeyExtractor Extracts
# Out:
Evaluation {
  'analysis': PCollection[Extracts] # Final Extracts
}

WriteResults

# In:
Evaluation {
  'metrics': PCollection[Tuple[slicer.SliceKeyType, Dict[Text, Any]]]  # Tuples of (slice key, dictionary from metric key to metric values)
  'plots': PCollection[Tuple[slicer.SliceKeyType, Dict[Text, Any]]]  # Tuples of (slice key, dictionary from plot key to plot values)
  'analysis': PCollection[Extracts] # Final Extracts
}
# Out: metrics, plots, and analysis files