# How to choose cross-entropy loss in TensorFlow?

Classification problems, such as logistic regression or multinomial logistic regression, optimize a cross-entropy loss. Normally, the cross-entropy layer follows the softmax layer, which produces probability distribution.

In tensorflow, there are at least a dozen of different cross-entropy loss functions:

• `tf.losses.softmax_cross_entropy`
• `tf.losses.sparse_softmax_cross_entropy`
• `tf.losses.sigmoid_cross_entropy`
• `tf.contrib.losses.softmax_cross_entropy`
• `tf.contrib.losses.sigmoid_cross_entropy`
• `tf.nn.softmax_cross_entropy_with_logits`
• `tf.nn.sigmoid_cross_entropy_with_logits`
• ...

Which one works only for binary classification and which are suitable for multi-class problems? When should you use `sigmoid` instead of `softmax`? How are `sparse` functions different from others and why is it only `softmax`?

Related (more math-oriented) discussion: What are the differences between all these cross-entropy losses in Keras and TensorFlow?.

## Preliminary facts

• In functional sense, the sigmoid is a partial case of the softmax function, when the number of classes equals 2. Both of them do the same operation: transform the logits (see below) to probabilities.

In simple binary classification, there's no big difference between the two, however in case of multinomial classification, sigmoid allows to deal with non-exclusive labels (a.k.a. multi-labels), while softmax deals with exclusive classes (see below).

• A logit (also called a score) is a raw unscaled value associated with a class, before computing the probability. In terms of neural network architecture, this means that a logit is an output of a dense (fully-connected) layer.

Tensorflow naming is a bit strange: all of the functions below accept logits, not probabilities, and apply the transformation themselves (which is simply more efficient).

## Sigmoid functions family

As stated earlier, `sigmoid` loss function is for binary classification. But tensorflow functions are more general and allow to do multi-label classification, when the classes are independent. In other words, `tf.nn.sigmoid_cross_entropy_with_logits` solves `N` binary classifications at once.

The labels must be one-hot encoded or can contain soft class probabilities.

`tf.losses.sigmoid_cross_entropy` in addition allows to set the in-batch weights, i.e. make some examples more important than others. `tf.nn.weighted_cross_entropy_with_logits` allows to set class weights (remember, the classification is binary), i.e. make positive errors larger than negative errors. This is useful when the training data is unbalanced.

## Softmax functions family

These loss functions should be used for multinomial mutually exclusive classification, i.e. pick one out of `N` classes. Also applicable when `N = 2`.

The labels must be one-hot encoded or can contain soft class probabilities: a particular example can belong to class A with 50% probability and class B with 50% probability. Note that strictly speaking it doesn't mean that it belongs to both classes, but one can interpret the probabilities this way.

Just like in `sigmoid` family, `tf.losses.softmax_cross_entropy` allows to set the in-batch weights, i.e. make some examples more important than others. As far as I know, as of tensorflow 1.3, there's no built-in way to set class weights.

[UPD] In tensorflow 1.5, `v2` version was introduced and the original `softmax_cross_entropy_with_logits` loss got deprecated. The only difference between them is that in a newer version, backpropagation happens into both logits and labels (here's a discussion why this may be useful).

## Sparse functions family

Like ordinary `softmax` above, these loss functions should be used for multinomial mutually exclusive classification, i.e. pick one out of `N` classes. The difference is in labels encoding: the classes are specified as integers (class index), not one-hot vectors. Obviously, this doesn't allow soft classes, but it can save some memory when there are thousands or millions of classes. However, note that `logits` argument must still contain logits per each class, thus it consumes at least `[batch_size, classes]` memory.

Like above, `tf.losses` version has a `weights` argument which allows to set the in-batch weights.

## Sampled softmax functions family

These functions provide another alternative for dealing with huge number of classes. Instead of computing and comparing an exact probability distribution, they compute a loss estimate from a random sample.

The arguments `weights` and `biases` specify a separate fully-connected layer that is used to compute the logits for a chosen sample.

Like above, `labels` are not one-hot encoded, but have the shape `[batch_size, num_true]`.

Sampled functions are only suitable for training. In test time, it's recommended to use a standard `softmax` loss (either sparse or one-hot) to get an actual distribution.

Another alternative loss is `tf.nn.nce_loss`, which performs noise-contrastive estimation (if you're interested, see this very detailed discussion). I've included this function to the softmax family, because NCE guarantees approximation to softmax in the limit.

• May I ask for a point of clarification regarding sigmoid cross entropy (sigCE)? If it solves for `N` binary classification tasks at once, is `N = prod(output.shape)`, e.g. `shape = [batch, examples, channels]; N = (batch * examples * channels)`? If `tf.losses` expect "logits" (output of network), should I also return the probabilities for ease of use? could you maybe look at stackoverflow.com/questions/53612973/… – SumNeuron Dec 5 '18 at 13:30

However, for version 1.5, `softmax_cross_entropy_with_logits_v2` must be used instead, while using its argument with the `argument key=...`, for example

``````softmax_cross_entropy_with_logits_v2(_sentinel=None, labels=y,
logits=my_prediction, dim=-1, name=None)
``````