HyperparameterHunter
Automatically save and learn from Experiment results, leading to long-term, persistent optimization that remembers all your tests.
HyperparameterHunter provides a wrapper for machine learning algorithms that saves all the important data. Simplify the experimentation and hyperparameter tuning process by letting HyperparameterHunter do the hard work of recording, organizing, and learning from your tests — all while using the same libraries you already do. Don't let any of your experiments go to waste, and start doing hyperparameter optimization the way it was meant to be.
- Installation:
pip install hyperparameter-hunter
- Source: https://github.com/HunterMcGushion/hyperparameter_hunter
- Documentation: https://hyperparameter-hunter.readthedocs.io
Features
- Automatically record Experiment results
- Truly informed hyperparameter optimization that automatically uses past Experiments
- Eliminate boilerplate code for cross-validation loops, predicting, and scoring
- Stop worrying about keeping track of hyperparameters, scores, or re-running the same Experiments
- Use the libraries and utilities you already love
How to Use HyperparameterHunter
Don’t think of HyperparameterHunter as another optimization library that you bring out only when its time to do hyperparameter optimization. Of course, it does optimization, but its better to view HyperparameterHunter as your own personal machine learning toolbox/assistant.
The idea is to start using HyperparameterHunter immediately. Run all of your benchmark/one-off experiments through it.
The more you use HyperparameterHunter, the better your results will be. If you just use it for optimization, sure, it’ll do what you want, but that’s missing the point of HyperparameterHunter.
If you’ve been using it for experimentation and optimization along the entire course of your project, then when you decide to do hyperparameter optimization, HyperparameterHunter is already aware of all that you’ve done, and that’s when HyperparameterHunter does something remarkable. It doesn’t start optimization from scratch like other libraries. It starts from all of the Experiments and previous optimization rounds you’ve already run through it.
Getting Started
1) Environment:
Set up an Environment to organize Experiments and Optimization results.
Any Experiments or Optimization rounds we perform will use our active Environment.
from hyperparameter_hunter import Environment, CVExperiment
import pandas as pd
from sklearn.datasets import load_breast_cancer
from sklearn.model_selection import StratifiedKFold
data = load_breast_cancer()
df = pd.DataFrame(data=data.data, columns=data.feature_names)
df['target'] = data.target
env = Environment(
train_dataset=df, # Add holdout/test dataframes, too
results_path='path/to/results/directory', # Where your result files will go
metrics=['roc_auc_score'], # Callables, or strings referring to `sklearn.metrics`
cv_type=StratifiedKFold, # Class, or string in `sklearn.model_selection`
cv_params=dict(n_splits=5, shuffle=True, random_state=32)
)
2) Individual Experimentation:
Perform Experiments with your favorite libraries simply by providing model initializers and hyperparameters
Keras
# Same format used by `keras.wrappers.scikit_learn`. Nothing new to learn
def build_fn(input_shape): # `input_shape` calculated for you
model = Sequential([
Dense(100, kernel_initializer='uniform', input_shape=input_shape, activation='relu'),
Dropout(0.5),
Dense(1, kernel_initializer='uniform', activation='sigmoid')
]) # All layer arguments saved (whether explicit or Keras default) for future use
model.compile(optimizer='adam', loss='binary_crossentropy', metrics=['accuracy'])
return model
experiment = CVExperiment(
model_initializer=KerasClassifier,
model_init_params=build_fn, # We interpret your build_fn to save hyperparameters in a useful, readable format
model_extra_params=dict(
callbacks=[ReduceLROnPlateau(patience=5)], # Use Keras callbacks
batch_size=32, epochs=10, verbose=0 # Fit/predict arguments
)
)
SKLearn
experiment = CVExperiment(
model_initializer=LinearSVC, # (Or any of the dozens of other SK-Learn algorithms)
model_init_params=dict(penalty='l1', C=0.9) # Default values used and recorded for kwargs not given
)
XGBoost
experiment = CVExperiment(
model_initializer=XGBClassifier,
model_init_params=dict(objective='reg:linear', max_depth=3, n_estimators=100, subsample=0.5)
)
LightGBM
experiment = CVExperiment(
model_initializer=LGBMClassifier,
model_init_params=dict(boosting_type='gbdt', num_leaves=31, max_depth=-1, min_child_samples=5, subsample=0.5)
)
CatBoost
experiment = CVExperiment(
model_initializer=CatboostClassifier,
model_init_params=dict(iterations=500, learning_rate=0.01, depth=7, allow_writing_files=False),
model_extra_params=dict(fit=dict(verbose=True)) # Send kwargs to `fit` and other extra methods
)
RGF
experiment = CVExperiment(
model_initializer=RGFClassifier,
model_init_params=dict(max_leaf=1000, algorithm='RGF', min_samples_leaf=10)
)
3) Hyperparameter Optimization:
Just like Experiments, but if you want to optimize a hyperparameter, use the classes imported below
from hyperparameter_hunter import Real, Integer, Categorical
from hyperparameter_hunter import optimization as opt
Keras
def build_fn(input_shape):
model = Sequential([
Dense(Integer(50, 150), input_shape=input_shape, activation='relu'),
Dropout(Real(0.2, 0.7)),
Dense(1, activation=Categorical(['sigmoid', 'softmax']))
])
model.compile(
optimizer=Categorical(['adam', 'rmsprop', 'sgd', 'adadelta']),
loss='binary_crossentropy', metrics=['accuracy']
)
return model
optimizer = opt.RandomForestOptPro(iterations=7)
optimizer.forge_experiment(
model_initializer=KerasClassifier,
model_init_params=build_fn,
model_extra_params=dict(
callbacks=[ReduceLROnPlateau(patience=Integer(5, 10))],
batch_size=Categorical([32, 64]),
epochs=10, verbose=0
)
)
optimizer.go()
SKLearn
optimizer = opt.DummyOptPro(iterations=42)
optimizer.forge_experiment(
model_initializer=AdaBoostClassifier, # (Or any of the dozens of other SKLearn algorithms)
model_init_params=dict(
n_estimators=Integer(75, 150),
learning_rate=Real(0.8, 1.3),
algorithm='SAMME.R'
)
)
optimizer.go()
XGBoost
optimizer = opt.BayesianOptPro(iterations=10)
optimizer.forge_experiment(
model_initializer=XGBClassifier,
model_init_params=dict(
max_depth=Integer(low=2, high=20),
learning_rate=Real(0.0001, 0.5),
n_estimators=200,
subsample=0.5,
booster=Categorical(['gbtree', 'gblinear', 'dart']),
)
)
optimizer.go()
LightGBM
optimizer = opt.BayesianOptPro(iterations=100)
optimizer.forge_experiment(
model_initializer=LGBMClassifier,
model_init_params=dict(
boosting_type=Categorical(['gbdt', 'dart']),
num_leaves=Integer(5, 20),
max_depth=-1,
min_child_samples=5,
subsample=0.5
)
)
optimizer.go()
CatBoost
optimizer = opt.GradientBoostedRegressionTreeOptPro(iterations=32)
optimizer.forge_experiment(
model_initializer=CatBoostClassifier,
model_init_params=dict(
iterations=100,
eval_metric=Categorical(['Logloss', 'Accuracy', 'AUC']),
learning_rate=Real(low=0.0001, high=0.5),
depth=Integer(4, 7),
allow_writing_files=False
)
)
optimizer.go()
RGF
optimizer = opt.ExtraTreesOptPro(iterations=10)
optimizer.forge_experiment(
model_initializer=RGFClassifier,
model_init_params=dict(
max_leaf=1000,
algorithm=Categorical(['RGF', 'RGF_Opt', 'RGF_Sib']),
l2=Real(0.01, 0.3),
normalize=Categorical([True, False]),
learning_rate=Real(0.3, 0.7),
loss=Categorical(['LS', 'Expo', 'Log', 'Abs'])
)
)
optimizer.go()
Output File Structure
This is a simple illustration of the file structure you can expect your Experiment
s to generate. For an in-depth description of the directory structure and the contents of the various files, see the File Structure Overview section in the documentation. However, the essentials are as follows:
- An
Experiment
adds a file to each HyperparameterHunterAssets/Experiments subdirectory, named byexperiment_id
- Each
Experiment
also adds an entry to HyperparameterHunterAssets/Leaderboards/GlobalLeaderboard.csv - Customize which files are created via
Environment
'sfile_blacklist
anddo_full_save
kwargs (documented here)
HyperparameterHunterAssets
| Heartbeat.log
|
└───Experiments
| |
| └───Descriptions
| | | <Files describing Experiment results, conditions, etc.>.json
| |
| └───Predictions<OOF/Holdout/Test>
| | | <Files containing Experiment predictions for the indicated dataset>.csv
| |
| └───Heartbeats
| | | <Files containing the log produced by the Experiment>.log
| |
| └───ScriptBackups
| | <Files containing a copy of the script that created the Experiment>.py
|
└───Leaderboards
| | GlobalLeaderboard.csv
| | <Other leaderboards>.csv
|
└───TestedKeys
| | <Files named by Environment key, containing hyperparameter keys>.json
|
└───KeyAttributeLookup
| <Files linking complex objects used in Experiments to their hashes>
Installation
pip install hyperparameter-hunter
If you like being on the cutting-edge, and you want all the latest developments, run:
pip install git+https://github.com/HunterMcGushion/hyperparameter_hunter.git
If you want to contribute to HyperparameterHunter, get started here.
I Still Don't Get It
That's ok. Don't feel bad. It's a bit weird to wrap your head around. Here's an example that illustrates how everything is related:
from hyperparameter_hunter import Environment, CVExperiment, BayesianOptPro, Integer
from hyperparameter_hunter.utils.learning_utils import get_breast_cancer_data
from xgboost import XGBClassifier
# Start by creating an `Environment` - This is where you define how Experiments (and optimization) will be conducted
env = Environment(
train_dataset=get_breast_cancer_data(target='target'),
results_path='HyperparameterHunterAssets',
metrics=['roc_auc_score'],
cv_type='StratifiedKFold',
cv_params=dict(n_splits=10, shuffle=True, random_state=32),
)
# Now, conduct an `Experiment`
# This tells HyperparameterHunter to use the settings in the active `Environment` to train a model with these hyperparameters
experiment = CVExperiment(
model_initializer=XGBClassifier,
model_init_params=dict(
objective='reg:linear',
max_depth=3
)
)
# That's it. No annoying boilerplate code to fit models and record results
# Now, the `Environment`'s `results_path` directory will contain new files describing the Experiment just conducted
# Time for the fun part. We'll set up some hyperparameter optimization by first defining the `OptPro` (Optimization Protocol) we want
optimizer = BayesianOptPro(verbose=1)
# Now we're going to say which hyperparameters we want to optimize.
# Notice how this looks just like our `experiment` above
optimizer.forge_experiment(
model_initializer=XGBClassifier,
model_init_params=dict(
objective='reg:linear', # We're setting this as a constant guideline - Not one to optimize
max_depth=Integer(2, 10) # Instead of using an int like the `experiment` above, we provide a space to search
)
)
# Notice that our range for `max_depth` includes the `max_depth=3` value we used in our `experiment` earlier
optimizer.go() # Now, we go
assert experiment.experiment_id in [_[2] for _ in optimizer.similar_experiments]
# Here we're verifying that the `experiment` we conducted first was found by `optimizer` and used as learning material
# You can also see via the console that we found `experiment`'s saved files, and used it to start optimization
last_experiment_id = optimizer.current_experiment.experiment_id
# Let's save the id of the experiment that was just conducted by `optimizer`
optimizer.go() # Now, we'll start up `optimizer` again...
# And we can see that this second optimization round learned from both our first `experiment` and our first optimization round
assert experiment.experiment_id in [_[2] for _ in optimizer.similar_experiments]
assert last_experiment_id in [_[2] for _ in optimizer.similar_experiments]
# It even did all this without us having to tell it what experiments to learn from
# Now think about how much better your hyperparameter optimization will be when it learns from:
# - All your past experiments, and
# - All your past optimization rounds
# And the best part: HyperparameterHunter figures out which experiments are compatible all on its own
# You don't have to worry about telling it that KFold=5 is different from KFold=10,
# Or that max_depth=12 is outside of max_depth=Integer(2, 10)
Tested Libraries
- Keras
- scikit-learn
- LightGBM
- CatBoost
- XGBoost
- rgf_python
- ... More on the way
Gotchas/FAQs
These are some things that might "getcha"
General:
- Can't provide initial search points to
OptPro
?- This is intentional. If you want your optimization rounds to start with specific search points (that you haven't recorded yet), simply perform a
CVExperiment
before initializing yourOptPro
- Assuming the two have the same guideline hyperparameters and the
Experiment
fits within the search space defined by yourOptPro
, the optimizer will locate and read in the results of theExperiment
- Keep in mind, you'll probably want to remove the
Experiment
after you've done it once, as the results have been saved. Leaving it there will just execute the sameExperiment
over and over again
- This is intentional. If you want your optimization rounds to start with specific search points (that you haven't recorded yet), simply perform a
- After changing things in my "HyperparameterHunterAssets" directory, everything stopped working
- Yeah, don't do that. Especially not with "Descriptions", "Leaderboards", or "TestedKeys"
- HyperparameterHunter figures out what's going on by reading these files directly.
- Removing them, or changing their contents can break a lot of HyperparameterHunter's functionality
Keras:
- Can't find similar Experiments with simple Dense/Activation neural networks?
- This is likely caused by switching between using a separate
Activation
layer, and providing aDense
layer with theactivation
kwarg - Each layer is treated as its own little set of hyperparameters (as well as being a hyperparameter, itself), which means that as far as HyperparameterHunter is concerned, the following two examples are NOT equivalent:
Dense(10, activation=‘sigmoid’)
Dense(10); Activation(‘sigmoid’)
- We’re working on this, but for now, the workaround is just to be consistent with how you add activations to your models
- Either use separate
Activation
layers, or provideactivation
kwargs to other layers, and stick with it!
- Either use separate
- This is likely caused by switching between using a separate
- Can't optimize the
model.compile
arguments:optimizer
andoptimizer_params
at the same time?- This happens because Keras’
optimizers
expect different arguments - For example, when
optimizer=Categorical(['adam', 'rmsprop'])
, there are two different possible dicts ofoptimizer_params
- For now, you can only optimize
optimizer
, andoptimizer_params
separately - A good way to do this might be to select a few optimizers you want to test, and don’t provide an
optimizer_params
value. That way, eachoptimizer
will use its default parameters- Then you can select which
optimizer
was the best, and setoptimizer=<best optimizer>
, then move on to tuningoptimizer_params
, with arguments specific to theoptimizer
you selected
- Then you can select which
- This happens because Keras’
CatBoost:
- Can't find similar Experiments for CatBoost?
- This may be happening because the default values for the kwargs expected in CatBoost’s model
__init__
methods are defined somewhere else, and given placeholder values ofNone
in their signatures - Because of this, HyperparameterHunter assumes that the default value for an argument really is
None
if you don’t explicitly provide a value for that argument - This is obviously not the case, but I just can’t seem to figure out where the actual default values used by CatBoost are located, so if anyone knows how to remedy this situation, I would love your help!
- This may be happening because the default values for the kwargs expected in CatBoost’s model