BOML is a modularized optimization library that unifies several ML algorithms into a common bilevel optimization framework. It provides interfaces to implement popular bilevel optimization algorithms, so that you could quickly build your own meta learning neural network and test its performance.
ReadMe.md contains brief introduction to implement meta-initialization-based and meta-feature-based methods in few-shot classification field. Except for algorithms which have been proposed, various combinations of lower level and upper level strategies are available.
Meta learning works fairly well when facing incoming new tasks by learning an initialization with favorable generalization capability. And it also has good performance even provided with a small amount of training data available, which gives birth to various solutions for different application such as few-shot learning problem.
We present a general bilevel optimization paradigm to unify different types of meta learning approaches, and the mathematical form could be summarized as below:
Here we illustrate the generic optimization process and hierarchically built strategies in the figure, which could be quikcly implemented in the following example.
For more detailed information of basic function and construction process, please refer to our Documentation orProject Page. Scripts in the directory named test_script are useful for constructing general training process.
Here we give recommended settings for specific hyper paremeters to quickly test performance of popular algorithms.
import boml
from boml import utils
from test_script.script_helper import *
dataset = boml.load_data.meta_omniglot(
std_num_classes=args.classes,
examples_train=args.examples_train,
examples_test=args.examples_test,
)
# create instance of BOMLExperiment for ong single task
ex = boml.BOMLExperiment(dataset)boml_ho = boml.BOMLOptimizer(
method="MetaInit", inner_method="Simple", outer_method="Simple"
)
meta_learner = boml_ho.meta_learner(_input=ex.x, dataset=dataset, meta_model="V1")
ex.model = boml_ho.base_learner(_input=ex.x, meta_learner=meta_learner)loss_inner = utils.cross_entropy(pred=ex.model.out, label=ex.y)
accuracy = utils.classification_acc(pred=ex.model.out, label=ex.y)
inner_grad = boml_ho.ll_problem(
inner_objective=loss_inner,
learning_rate=args.lr,
T=args.T,
experiment=ex,
var_list=ex.model.var_list,
)loss_outer = utils.cross_entropy(pred=ex.model.re_forward(ex.x_).out, label=ex.y_) # loss function
boml_ho.ul_problem(
outer_objective=loss_outer,
meta_learning_rate=args.meta_lr,
inner_grad=inner_grad,
meta_param=tf.get_collection(boml.extension.GraphKeys.METAPARAMETERS),
)# Only need to be called once after all the tasks are ready
boml_ho.aggregate_all()with tf.Session() as sess:
tf.global_variables_initializer().run(session=sess)
for itr in range(args.meta_train_iterations):
# Generate the feed_dict for calling run() everytime
train_batch = BatchQueueMock(
dataset.train, 1, args.meta_batch_size, utils.get_rand_state(1)
)
tr_fd, v_fd = utils.feed_dict(train_batch.get_single_batch(), ex)
# Meta training step
boml_ho.run(tr_fd, v_fd)
if itr % 100 == 0:
print(sess.run(loss_inner, utils.merge_dicts(tr_fd, v_fd)))- Hyperparameter optimization with approximate gradient(HOAG)
- Model-Agnostic Meta-Learning for Fast Adaptation of Deep Networks(MAML)
- On First-Order Meta-Learning Algorithms(FMAML)
- Meta-SGD: Learning to Learn Quickly for Few-Shot Learning(Meta-SGD)
- Bilevel Programming for Hyperparameter Optimization and Meta-Learning(RHG)
- Truncated Back-propagation for Bilevel Optimization(TG)
- Gradient-Based Meta-Learning with Learned Layerwise Metric and Subspace(MT-net)
- Meta-Learning with warped gradient Descent(WarpGrad))
- DARTS: Differentiable Architecture Search(DARTS)
- A Generic First-Order Algorithmic Framework for Bi-Level Programming Beyond Lower-Level Singleton(BDA)
MIT License
Copyright (c) 2020 Yaohua Liu
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