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Creates a Head
for multi-label classification.
Inherits From: Head
tf.estimator.MultiLabelHead(
n_classes,
weight_column=None,
thresholds=None,
label_vocabulary=None,
loss_reduction=tf.losses.Reduction.SUM_OVER_BATCH_SIZE,
loss_fn=None,
classes_for_class_based_metrics=None,
name=None
)
Multi-label classification handles the case where each example may have zero
or more associated labels, from a discrete set. This is distinct from
MultiClassHead
which has exactly one label per example.
Uses sigmoid_cross_entropy
loss average over classes and weighted sum over
the batch. Namely, if the input logits have shape [batch_size, n_classes]
,
the loss is the average over n_classes
and the weighted sum over
batch_size
.
The head expects logits
with shape [D0, D1, ... DN, n_classes]
. In many
applications, the shape is [batch_size, n_classes]
.
Labels can be:
- A multi-hot tensor of shape
[D0, D1, ... DN, n_classes]
- An integer
SparseTensor
of class indices. Thedense_shape
must be[D0, D1, ... DN, ?]
and the values within[0, n_classes)
. - If
label_vocabulary
is given, a stringSparseTensor
. Thedense_shape
must be[D0, D1, ... DN, ?]
and the values withinlabel_vocabulary
or a multi-hot tensor of shape[D0, D1, ... DN, n_classes]
.
If weight_column
is specified, weights must be of shape
[D0, D1, ... DN]
, or [D0, D1, ... DN, 1]
.
Also supports custom loss_fn
. loss_fn
takes (labels, logits)
or
(labels, logits, features)
as arguments and returns unreduced loss with
shape [D0, D1, ... DN, 1]
. loss_fn
must support indicator labels
with
shape [D0, D1, ... DN, n_classes]
. Namely, the head applies
label_vocabulary
to the input labels before passing them to loss_fn
.
Usage:
n_classes = 2
head = tf.estimator.MultiLabelHead(n_classes)
logits = np.array([[-1., 1.], [-1.5, 1.5]], dtype=np.float32)
labels = np.array([[1, 0], [1, 1]], dtype=np.int64)
features = {'x': np.array([[41], [42]], dtype=np.int32)}
# expected_loss = sum(_sigmoid_cross_entropy(labels, logits)) / batch_size
# = sum(1.31326169, 0.9514133) / 2 = 1.13
loss = head.loss(labels, logits, features=features)
print('{:.2f}'.format(loss.numpy()))
1.13
eval_metrics = head.metrics()
updated_metrics = head.update_metrics(
eval_metrics, features, logits, labels)
for k in sorted(updated_metrics):
print('{} : {:.2f}'.format(k, updated_metrics[k].result().numpy()))
auc : 0.33
auc_precision_recall : 0.77
average_loss : 1.13
preds = head.predictions(logits)
print(preds['logits'])
tf.Tensor(
[[-1. 1. ]
[-1.5 1.5]], shape=(2, 2), dtype=float32)
Usage with a canned estimator:
my_head = tf.estimator.MultiLabelHead(n_classes=3)
my_estimator = tf.estimator.DNNEstimator(
head=my_head,
hidden_units=...,
feature_columns=...)
It can also be used with a custom model_fn
. Example:
def _my_model_fn(features, labels, mode):
my_head = tf.estimator.MultiLabelHead(n_classes=3)
logits = tf.keras.Model(...)(features)
return my_head.create_estimator_spec(
features=features,
mode=mode,
labels=labels,
optimizer=tf.keras.optimizers.Adagrad(lr=0.1),
logits=logits)
my_estimator = tf.estimator.Estimator(model_fn=_my_model_fn)
Args | |
---|---|
n_classes
|
Number of classes, must be greater than 1 (for 1 class, use
BinaryClassHead ).
|
weight_column
|
A string or a NumericColumn created by
tf.feature_column.numeric_column defining feature column representing
weights. It is used to down weight or boost examples during training. It
will be multiplied by the loss of the example. Per-class weighting is not
supported.
|
thresholds
|
Iterable of floats in the range (0, 1) . Accuracy, precision
and recall metrics are evaluated for each threshold value. The threshold
is applied to the predicted probabilities, i.e. above the threshold is
true , below is false .
|
label_vocabulary
|
A list of strings represents possible label values. If it
is not given, that means labels are already encoded as integer within [0,
n_classes) or multi-hot Tensor. If given, labels must be SparseTensor
string type and have any value in label_vocabulary . Also there will be
errors if vocabulary is not provided and labels are string.
|
loss_reduction
|
One of tf.losses.Reduction except NONE . Decides how to
reduce training loss over batch. Defaults to SUM_OVER_BATCH_SIZE , namely
weighted sum of losses divided by batch size.
|
loss_fn
|
Optional loss function. |
classes_for_class_based_metrics
|
List of integer class IDs or string class
names for which per-class metrics are evaluated. If integers, all must be
in the range [0, n_classes - 1] . If strings, all must be in
label_vocabulary .
|
name
|
Name of the head. If provided, summary and metrics keys will be
suffixed by "/" + name . Also used as name_scope when creating ops.
|
Attributes | |
---|---|
logits_dimension
|
See base_head.Head for details.
|
loss_reduction
|
See base_head.Head for details.
|
name
|
See base_head.Head for details.
|
Methods
create_estimator_spec
create_estimator_spec(
features,
mode,
logits,
labels=None,
optimizer=None,
trainable_variables=None,
train_op_fn=None,
update_ops=None,
regularization_losses=None
)
Returns EstimatorSpec
that a model_fn can return.
It is recommended to pass all args via name.
Args | |
---|---|
features
|
Input dict mapping string feature names to Tensor or
SparseTensor objects containing the values for that feature in a
minibatch. Often to be used to fetch example-weight tensor.
|
mode
|
Estimator's ModeKeys .
|
logits
|
Logits Tensor to be used by the head.
|
labels
|
Labels Tensor , or dict mapping string label names to Tensor
objects of the label values.
|
optimizer
|
An tf.keras.optimizers.Optimizer instance to optimize the
loss in TRAIN mode. Namely, sets train_op = optimizer.get_updates(loss,
trainable_variables) , which updates variables to minimize loss .
|
trainable_variables
|
A list or tuple of Variable objects to update to
minimize loss . In Tensorflow 1.x, by default these are the list of
variables collected in the graph under the key
GraphKeys.TRAINABLE_VARIABLES . As Tensorflow 2.x doesn't have
collections and GraphKeys, trainable_variables need to be passed
explicitly here.
|
train_op_fn
|
Function that takes a scalar loss Tensor and returns an op
to optimize the model with the loss in TRAIN mode. Used if optimizer
is None . Exactly one of train_op_fn and optimizer must be set in
TRAIN mode. By default, it is None in other modes. If you want to
optimize loss yourself, you can pass lambda _: tf.no_op() and then use
EstimatorSpec.loss to compute and apply gradients.
|
update_ops
|
A list or tuple of update ops to be run at training time. For example, layers such as BatchNormalization create mean and variance update ops that need to be run at training time. In Tensorflow 1.x, these are thrown into an UPDATE_OPS collection. As Tensorflow 2.x doesn't have collections, update_ops need to be passed explicitly here. |
regularization_losses
|
A list of additional scalar losses to be added to the training loss, such as regularization losses. |
Returns | |
---|---|
EstimatorSpec .
|
loss
loss(
labels, logits, features=None, mode=None, regularization_losses=None
)
Returns regularized training loss. See base_head.Head
for details.
metrics
metrics(
regularization_losses=None
)
Creates metrics. See base_head.Head
for details.
predictions
predictions(
logits, keys=None
)
Return predictions based on keys.
See base_head.Head
for details.
Args | |
---|---|
logits
|
logits Tensor with shape [D0, D1, ... DN, logits_dimension] .
For many applications, the shape is [batch_size, logits_dimension] .
|
keys
|
a list of prediction keys. Key can be either the class variable of prediction_keys.PredictionKeys or its string value, such as: prediction_keys.PredictionKeys.LOGITS or 'logits'. |
Returns | |
---|---|
A dict of predictions. |
update_metrics
update_metrics(
eval_metrics, features, logits, labels, regularization_losses=None
)
Updates eval metrics. See base_head.Head
for details.